Suturing Device and Method for Sealing an Opening in a Blood Vessel or Other Biological Structure

ABSTRACT

A suturing device includes a handle, an elongated body, at least one suture snag, at least one pair of needles, and at least one suture pair. The suture snag is moveable between a deployed position in which two distal arm portions thereof radially extend away from the elongated body and a retracted position in which the two distal arm portions are disposed within the elongated body. The suture pair is slidingly disposed through the needle pair. The suturing device deploys the suture snag within a vessel adjacent to an arteriotomy, extends the needle pair through a vessel wall around the arteriotomy and through the deployed suture snag, extends the suture pair beyond the distal ends of the needle pair, and then utilizes the suture snag to capture the extended suture pair by retracting the suture snag to pull first or distal ends of the sutures back into the suturing device. An inflatable balloon or an expandable suture capture component may be alternatives to the suture snag for capturing the suture ends.

CROSS-REFERENCE TO RELATED APPLICATION

This application is a continuation-in-part of U.S. application Ser. No.13/802,551, filed Mar. 13, 2013, which is hereby incorporated byreference herein in its entirety

FIELD OF THE INVENTION

The present invention relates to medical suturing devices, and moreparticularly, to suturing devices for closing an opening in an arterialor other biological tissue wall that is not directly accessible to auser.

BACKGROUND OF THE INVENTION

Various cardiovascular procedures, such as angioplasty, stent placementand atherectomy, require gaining access to the vasculature. Withreference to FIGS. 1 and 2, access to the vasculature of a patient 100typically is through the femoral artery and is percutaneous, involvinginsertion of a needle (not shown), and in some cases a dilator (notshown), in the region of the groin to form a track 104 throughsubcutaneous tissue 106 and to puncture and create an arteriotomy V_(A)in a vessel wall V_(W) of the femoral artery. A guidewire GW is thenadvanced through the needle and into the femoral artery. The needle anddilator, if present, are then removed. A catheter or otherinterventional device 102 is then advanced over the guidewire GW, alongthe track 104 and into the femoral artery in order to perform theselected procedure.

The size of the puncture opening in the artery corresponds to the sizeof the catheter or interventional device used, and such devices maytypically range in diameter from 5 French for a diagnostic procedure to6-20 French for a therapeutic procedure. In some cases, medical suturingsystems are utilized to “pre-close” the arteriotomy V_(A) by positioningone or more stitches adjacent to interventional device 102 that resultin hemostasis of the arteriotomy V_(A) around the interventional device102 during the procedure. After the procedure is completed and theinterventional device(s) are removed, the stitches positioned by themedical suturing system are utilized to fully close the arteriotomyV_(A).

In other cases, i.e., when the size of the arteriotomy is relativelysmall, such pre-closure is not required and a medical suturing system orother technique is utilized to close the arteriotomy after theinterventional device(s) are removed. A number of other techniques areknown to facilitate closure and healing of the arteriotomy. Onetechnique includes application of pressure at the puncture site for arelatively extended length of time. More particularly, compression hastraditionally been applied to the puncture site for at least 30-45minutes for the wound to close naturally after removal of the catheter.Patients are required to remain lying down, essentially motionless andoften with a heavy sandbag placed on their upper leg, for several hoursto ensure that the bleeding has stopped. The recovery time from themedical procedure may be as little as half of an hour, but the recoverytime from the wound can exceed twenty-four hours. Longer recovery timesmay result in increased expenses, increased patient discomfort, andgreater the risk of complications. Other approaches to arteriotomyclosure include a compression clamp device, a thrombotic or collagenplug, biological adhesives adapted to seal the arteriotomy, and/orstapling devices.

Medical suturing systems that have been proposed facilitate closure andhealing of the arteriotomy and resolve some of the concerns associatedwith arteriotomy closure during and after vascular catheterizationprocedures. However, a need in the art still exists for a medicalsuturing system that consistently and reliably facilitates closure andhealing of the arteriotomy.

BRIEF SUMMARY OF THE INVENTION

Embodiments hereof relate to a suturing device including a handle, anelongated body coupled to a distal end of the handle, and a shaftslidingly disposed within the handle and the elongated body. Anexpandable suture capture component is mounted on a distal portion ofthe shaft, the expandable suture capture component being operable toalternate between a deployed configuration in which the expandablesuture capture component radially expands and extends away from theelongated body and a compressed configuration in which the expandablesuture capture component is disposed within the elongated body. Thesuturing device also includes at least one pair of needles moveable to adeployed position in which the at least one pair of needles distallyextend from the distal end of the elongated body and into the expandablesuture capture component with the expandable suture capture component inits deployed configuration and a retracted position in which the atleast one pair of needles is disposed within the elongated body. Eachneedle includes a distal end configured to penetrate through a vesselwall.

Embodiments hereof also relate to a suturing device for positioning asuture in situ, the suturing device including a handle, an elongatedbody coupled to a distal end of the handle, and a shaft slidinglydisposed within the handle and the elongated body. The handle has afirst actuation mechanism and a second actuation mechanism, wherein thesecond actuation mechanism includes a suture holder and a needle holderdisposed within the handle. The shaft is moveable via the firstactuation mechanism. An expandable suture capture component is mountedon a distal portion of the shaft and the expandable suture capturecomponent is moveable between a deployed configuration in which theexpandable suture capture component radially expands and extends awayfrom the elongated body and a compressed configuration in which theexpandable suture capture component is disposed within the elongatedbody. The suturing device also includes a pair of needles extendingthrough the handle and through the elongated body, each needle includinga distal end configured to penetrate through a vessel wall. The pair ofneedles is coupled to the needle holder and the second actuationmechanism moves the pair of needles to a deployed position in which thepair of needles distally extend away from the distal end of theelongated body and into the expandable suture capture component with theexpandable suture capture component in its deployed configuration and aretracted position in which the pair of needles is disposed within theelongated body. A pair of sutures is slidingly disposed through the pairof needles. The sutures are coupled to the suture holder when theneedles are in their deployed position and are disengaged from thesuture holder when the needles are in their retracted position andwherein the second actuation mechanism moves the pair of suturesrelative to the pair of needles from a loaded position in which eachfirst end of each suture is disposed within its respective needle to adeployed position in which each first end of each suture extendsdistally beyond the distal end of its respective needle.

Embodiments hereof also relate to a method of positioning a suture at anarteriotomy of a vessel wall of a vessel. A distal end of a suturingdevice is positioned through the arteriotomy, wherein the suturingdevice includes a handle, an elongated body coupled to a distal end ofthe handle, and a shaft slidingly disposed within the handle and theelongated body. An expandable suture capture component is mounted on adistal portion of the shaft and is in a compressed configuration inwhich the expandable suture capture component is disposed within theelongated body. The expandable suture capture component is expanded to adeployed configuration in which the expandable suture capture componentradially expands and extends away from the elongated body, wherein theexpanded expandable suture capture component is positioned within thevessel. At least one pair of needles of the suturing device is distallyextended from a loaded position in which the at least one pair ofneedles is disposed within the elongated body to a deployed position inwhich the at least one pair of needles distally extend from a distal endof the elongated body and penetrate through the vessel wall and throughthe expanded expandable suture capture component. A suture is slidinglydisposed through the lumen of each needle and each suture isconcurrently carried with its respective needle during the step ofdistally extending the at least one pair of needles to the deployedposition.

BRIEF DESCRIPTION OF DRAWINGS

The foregoing and other features and advantages of the invention will beapparent from the following description of embodiments hereof asillustrated in the accompanying drawings. The accompanying drawings,which are incorporated herein and form a part of the specification,further serve to explain the principles of the invention and to enable aperson skilled in the pertinent art to make and use the invention. Thedrawings are not to scale.

FIGS. 1 and 2 illustrate the introduction of an introducer sheath intothe vasculature via the femoral artery, thereby forming an arteriotomyin a vessel wall of the femoral artery.

FIG. 3 is a perspective view of a suturing device according to anembodiment hereof for sealing or closing an arteriotomy, wherein thesuturing device is in a delivery configuration in which the suture snagsare in a retracted position and the needles and sutures are in a loadedposition.

FIG. 3A is a sectional view of FIG. 3 taken along line A-A.

FIG. 3B is a cross-sectional view of FIG. 3 taken along line B-B.

FIG. 4 is a side view illustration of a first step of a method of usingthe suturing device of FIG. 3 according to an embodiment hereof, whereinthe suturing device is advanced towards an arteriotomy.

FIG. 4A is a sectional view of a proximal portion of handle of thesuturing device of FIG. 3, wherein the handle portion includes actuationmechanisms for deploying the needles and sutures with the actuationmechanisms being shown in a first or loaded position.

FIG. 4B is a sectional view of a distal portion of handle of thesuturing device of FIG. 3, wherein the handle portion includes actuationmechanisms for deploying the suture snags and the actuation mechanismsare shown in a retracted position.

FIG. 4C is a cutaway view of a proximal portion of the handle of thesuturing device of FIG. 3 exposing an actuation mechanism for deployingthe needles and sutures.

FIG. 4D is a sectional view taken along line D-D of FIG. 4C.

FIG. 4E is a sectional view of a distal portion of the suturing deviceof FIG. 3, wherein the suture snags are in the retracted position andthe needles and sutures are in the loaded position.

FIG. 4F is a perspective view of a transmission member of the suturingdevice of FIG. 3, wherein the transmission member is removed from thesuturing device for illustrative purposes only.

FIG. 4G is a sectional view taken along line G-G of FIG. 4D.

FIG. 5 is a side view illustration of a second step of the method ofusing the suturing device of FIG. 3 according to an embodiment hereof,wherein the suturing device is positioned through the arteriotomy.

FIG. 6 is a side view illustration of a third step of the method ofusing the suturing device of FIG. 3 according to an embodiment hereof,wherein suture snags of the suturing device are deployed.

FIG. 6A is a perspective view of a distal portion of the suturing deviceof FIG. 3, wherein the suture snags of the suturing device are deployed.

FIG. 6B is a sectional view of a distal portion of the suturing deviceof FIG. 3, wherein the suture snags of the suturing device are deployed.

FIG. 6C is a perspective view of a suture snag of FIG. 3 removed fromthe suturing device for illustrative purposes only, wherein the suturesnag is in a deployed position.

FIG. 6D is a sectional view of a distal portion of the handle of thesuturing device of FIG. 3 with the actuation mechanisms for deployingthe suture snags shown in a deployed position.

FIG. 6E is a perspective view of a distal portion of the suturing deviceof FIG. 3, wherein only one suture snag of the suturing device isdeployed.

FIG. 7 is a side view illustration of a fourth step of the method ofusing the suturing device of FIG. 3 according to an embodiment hereof,wherein a pair of needles with sutures therein are deployed to extendthrough the vessel wall adjacent to the arteriotomy.

FIG. 7A is a perspective view of a distal portion of the suturing deviceof FIG. 3, wherein the needles with the sutures therein are deployed.

FIG. 7B is a cutaway view of a distal portion of the handle of thesuturing device of FIG. 3 exposing actuation mechanisms for deployingthe needles and sutures with the top actuation mechanism shown in aneedle deployment position.

FIG. 7C is a sectional view taken along line C-C of FIG. 7B.

FIG. 8 is a side view illustration of a fifth step of the method ofusing the suturing device of FIG. 3 according to an embodiment hereof,wherein the sutures are deployed to extend beyond the distal ends of theneedles.

FIG. 8A is a perspective view of a distal portion of the suturing deviceof FIG. 3, wherein the sutures of the suturing device are deployed toextend beyond the distal ends of the needles.

FIG. 8B is a cutaway view of a proximal portion of the handle of thesuturing device of FIG. 3 exposing actuation mechanisms for deployingthe needles and sutures with the top actuation mechanism shown in asuture deployment position.

FIG. 8C is a sectional view of a proximal portion of the handle of thesuturing device of FIG. 3, wherein the actuation mechanisms forextending the needles and sutures are both shown in a fully extendedsuture deployment position.

FIG. 8D is a sectional view taken along line D-D of FIG. 8B.

FIG. 9 is a side view illustration of a sixth step of the method ofusing the suturing device of FIG. 3 according to an embodiment hereof,wherein the pair of needles have been proximally retracted leaving apair of sutures deployed within a corresponding pair of suture snags.

FIG. 9A is a perspective view of a distal portion of the suturing deviceof FIG. 3, wherein the pair of needles shown in FIG. 8A have beenproximally retracted leaving a pair of sutures deployed within acorresponding pair of suture snags.

FIG. 9B is a cutaway view of a proximal portion of the handle of thesuturing device of FIG. 3 exposing actuation mechanisms for deployingthe needles and sutures with the actuation mechanisms shown in needleretraction positions with the sutures deployed.

FIG. 9C is a sectional view of a proximal portion of the handle of thesuturing device of FIG. 3 exposing actuation mechanisms for deployingthe needles and sutures the actuation mechanisms are shown havingretracted the needles while the sutures remain extended.

FIG. 9D is a sectional view taken along line D-D of FIG. 9C.

FIG. 10 is a side view illustration of a seventh step of the method ofusing the suturing device of FIG. 3 according to an embodiment hereof,wherein two sutures are shown extending into the arteriotomy.

FIG. 11 is a side view illustration of an eighth step of the method ofusing the suturing device of FIG. 3 according to an embodiment hereof,wherein the suture snags of the suturing device are proximallyretracted, thereby capturing the suture ends.

FIG. 11A is a cutaway view of a distal portion of the handle of thesuturing device of FIG. 3 exposing actuation mechanisms for deployingand retracting the suture snags with the actuation mechanisms shown in aretracted position.

FIG. 11B is a sectional view of a portion of the handle of the suturingdevice of FIG. 3, wherein the handle portion includes actuationmechanisms for deploying and retracting the suture snags with theactuation mechanisms shown in a retracted position.

FIG. 12 is a top view illustration of another step of a method of useaccording to an embodiment hereof, wherein sutures having ends fastenedtogether extend through the vessel wall around the arteriotomy.

FIG. 13 is a top view illustration of another step of a method of useaccording to an embodiment hereof, wherein tension applied to thecoupled sutures closes the arteriotomy.

FIG. 14 is a perspective view of a distal end of a suturing deviceaccording to another embodiment hereof, wherein the suturing deviceincludes only a single suture snag and a pair of needles for positioninga pair of sutures.

FIG. 14A is a perspective view of FIG. 14 showing the internalcomponents in phantom.

FIG. 15 is a sectional view of a handle of the suturing device of FIG.14.

FIG. 15A is an enlarged sectional view of a distal portion of the handleof FIG. 15 illustrating an actuation mechanism for deploying the singlesuture snag.

FIG. 15B is an enlarged sectional view of a proximal portion of thehandle of FIG. 15 illustrating an actuation mechanism for deploying theneedles and the sutures associated therewith.

FIG. 15C is a perspective top view of the actuation mechanism of FIG.15B, wherein the housing of the handle is shown in phantom.

FIG. 15D is a sectional view taken along line D-D of FIG. 15B.

FIG. 16 is a perspective view of a distal end of a suturing deviceaccording to another embodiment hereof, wherein the suturing deviceincludes needles that bend when extended from the suturing device.

FIG. 17 is a perspective view of a suturing device according to anotherembodiment hereof for sealing or closing an arteriotomy, wherein thesuturing device is in a delivery configuration in which an inflatableballoon thereof is in a retracted position and the needles and suturesare in a loaded position.

FIG. 17A is a cross-sectional view of FIG. 17 taken along line A-A.

FIG. 17B is a cross-sectional view of FIG. 17 taken along line A-Aaccording to another embodiment hereof.

FIG. 18 is a side view of a distal portion of a transmission shaft andthe inflatable balloon coupled thereto, removed from the suturing devicefor illustrative purposes only, wherein the inflatable balloon is in thedelivery configuration.

FIG. 19 is a side view of the distal portion of the transmission shaftand the inflatable balloon of FIG. 18, removed from the suturing devicefor illustrative purposes only, wherein the inflatable balloon is in theexpanded or inflated configuration.

FIG. 19A is a cross-sectional view of FIG. 19 taken along line A-A.

FIG. 20 is a cross-sectional view of FIG. 19 taken along line A-Aaccording to another embodiment hereof, wherein the inflatable balloonincludes dual layers.

FIG. 21 is a cross-sectional view of FIG. 19 taken along line A-Aaccording to another embodiment hereof, wherein the inflatable balloonincludes multiple compartments.

FIG. 22 is a cross-sectional view of FIG. 19 taken along line A-Aaccording to another embodiment hereof, wherein the inflatable balloonincludes dual layers and multiple compartments.

FIG. 23 is a cross-sectional view of FIG. 19 taken along line 19-19according to another embodiment hereof, wherein the transmission shaftincludes multiple lumens for independent inflation of the multiplecompartments of the inflatable balloon.

FIG. 24 is a side view illustration of a first step of the method ofusing the suturing device of FIG. 17 according to an embodiment hereof,wherein the suturing device is advanced towards and positioned throughthe arteriotomy.

FIG. 25 is a side view illustration of a second step of the method ofusing the suturing device of FIG. 17 according to an embodiment hereof,wherein the inflatable balloon of the suturing device is distallyadvanced.

FIG. 26 is a side view illustration of a third step of the method ofusing the suturing device of FIG. 17 according to an embodiment hereof,wherein the inflatable balloon of the suturing device is inflated orradially expanded.

FIG. 27 is a side view illustration of a fourth step of the method ofusing the suturing device of FIG. 17 according to an embodiment hereof,wherein a pair of needles with sutures therein are deployed to extendthrough the vessel wall adjacent to the arteriotomy and into theinflated balloon.

FIG. 28 is a side view illustration of a fifth step of the method ofusing the suturing device of FIG. 17 according to an embodiment hereof,wherein the sutures are deployed to extend beyond the distal ends of theneedles.

FIG. 29 is a side view illustration of a sixth step of the method ofusing the suturing device of FIG. 17 according to an embodiment hereof,wherein the pair of needles have been proximally retracted leaving apair of sutures deployed within the inflated balloon.

FIG. 30 is a side view illustration of a seventh step of the method ofusing the suturing device of FIG. 17 according to an embodiment hereof,wherein two sutures are shown extending into the arteriotomy.

FIG. 31 is a side view illustration of an eighth step of the method ofusing the suturing device of FIG. 17 according to an embodiment hereof,wherein the inflatable balloon is deflated or unexpanded with the sutureends captured therein.

FIG. 32 is a side view illustration of a ninth step of the method ofusing the suturing device of FIG. 17 according to an embodiment hereof,wherein the transmission shaft and inflatable balloon coupled theretoare proximally retracted, thereby capturing the suture ends within thesuturing device.

FIG. 33 is a side view of a distal portion of a transmission shaft andan expandable suture capture component coupled thereto according toanother embodiment hereof, wherein the expandable suture capturecomponent is in the delivery configuration.

FIG. 34 is a side view of the distal portion of the transmission shaftand the expandable suture capture component of FIG. 33, wherein theexpandable suture capture component is in the expanded or deployedconfiguration.

FIG. 35 is a side view of an alternative expanded or deployedconfiguration of the expandable suture capture component of FIG. 34.

FIG. 36 is a side view of another alternative expanded or deployedconfiguration of the expandable suture capture component of FIG. 34.

FIG. 36A is a side view of another alternative expanded or deployedconfiguration of the expandable suture capture component of FIG. 34,wherein the expandable suture capture component is schematically shownwithin a vessel having a vessel wall VW.

FIG. 37 is a side view of a distal portion of a transmission shaft andan expandable suture capture component coupled thereto according toanother embodiment hereof, wherein the expandable suture capturecomponent is in the delivery configuration.

FIG. 38 is a side view of the distal portion of the transmission shaftand the expandable suture capture component of FIG. 37, wherein theexpandable suture capture component is in the expanded or deployedconfiguration.

FIG. 39 is a side view illustration of a first step of the method ofusing the suturing device of FIG. 33 according to an embodiment hereof,wherein the suturing device is advanced towards and positioned throughthe arteriotomy.

FIG. 40 is a side view illustration of a second step of the method ofusing the suturing device of FIG. 33 according to an embodiment hereof,wherein the expandable suture capture component of the suturing deviceis distally advanced in order to expand the expandable suture capturecomponent of the suturing device.

FIG. 41 is a side view illustration of a third step of the method ofusing the suturing device of FIG. 33 according to an embodiment hereof,wherein a pair of needles with sutures therein are deployed to extendthrough the vessel wall adjacent to the arteriotomy and into theexpandable suture capture component.

FIG. 42 is a side view illustration of a fourth step of the method ofusing the suturing device of FIG. 33 according to an embodiment hereof,wherein the sutures are deployed to extend beyond the distal ends of theneedles.

FIG. 43 is a side view illustration of a fifth step of the method ofusing the suturing device of FIG. 33 according to an embodiment hereof,wherein the pair of needles have been proximally retracted leaving apair of sutures deployed within the expandable suture capture component.

FIG. 44 is a side view illustration of a sixth step of the method ofusing the suturing device of FIG. 33 according to an embodiment hereof,wherein two sutures are shown extending into the arteriotomy.

FIG. 45 is a side view illustration of a seventh step of the method ofusing the suturing device of FIG. 33 according to an embodiment hereof,wherein the transmission shaft and expandable suture capture componentcoupled thereto are proximally retracted, thereby capturing the sutureends within the suturing device.

FIG. 46 is a side view of a distal portion of a transmission shaft andan expandable suture capture component coupled thereto according toanother embodiment hereof, wherein the expandable suture capturecomponent is in the delivery configuration.

FIG. 47 is a side view of the distal portion of the transmission shaftand the expandable suture capture component of FIG. 46, wherein theexpandable suture capture component is in the expanded or deployedconfiguration.

FIG. 48 is a side view of the distal portion of the transmission shaftand the expandable suture capture component coupled thereto according toanother embodiment hereof, wherein the expandable suture capturecomponent is in the expanded or deployed configuration.

FIG. 48A is a side view of another alternative expanded or deployedconfiguration of the expandable suture capture component of FIG. 48.

FIG. 48B is a side view of another alternative expanded or deployedconfiguration of the expandable suture capture component of FIG. 48.

DETAILED DESCRIPTION OF THE INVENTION

Specific embodiments of the present invention are now described withreference to the figures, wherein like reference numbers indicateidentical or functionally similar elements. The terms “distal” and“proximal” are used in the following description with respect to aposition or direction relative to the treating clinician. “Distal” or“distally” are a position distant from or in a direction away from theclinician. “Proximal” and “proximally” are a position near or in adirection toward the clinician.

The following detailed description is merely exemplary in nature and isnot intended to limit the invention or the application and uses of theinvention. Although the description of the invention is in the contextof treatment of an arteriotomy, which is used herein to refer to anopening, cut, or incision of an artery, the invention may also be usedin any other blood vessels or body passageways where it is deemeduseful. For example, the device could be used to suture openings orincisions of other tissue such as a patent ductus arteriosus, a patentforamen ovale, a heart defect, a puncture wound, and the like.Furthermore, there is no intention to be bound by any expressed orimplied theory presented in the preceding technical field, background,brief summary or the following detailed description.

Suturing devices according to embodiments hereof use a pair of needle toposition a pair of sutures beyond the boundaries or perimeter of anarteriotomy and then utilize a suture snag to capture the ends of thesutures and pull the suture ends back into the suturing device. Thecaptured sutures are then tied together to form a single stitch. Thesuturing devices may be used to seal a blood vessel during and/orfollowing an interventional catheterization procedure. As will beunderstood by one of ordinary skill in the art, the number of suturesnags and needles may vary depending upon the number of sutures beingpositioned by the suturing device. For instance, one suture snag and onepair of needles are utilized for positioning one pair of sutures at anarteriotomy, whereby the suture pair is then tied together to form asingle stitch, while two suture snags and two pairs of needles areutilized for positioning two pairs of sutures at an arteriotomy, wherebyeach suture pair is then tied together to form a total of two stitches.During delivery thereof, a first suture of a suture pair is housedwithin a first needle of a needle pair and a second suture of the suturepair is housed within a second needle of the needle pair. The first andsecond needles of the needle pair actuate or move together. Thus, aplurality of needles with a complementing number of suture snags may beincorporated into the device to accomplish the specific needs of theapplication. The embodiment of FIGS. 3-13 illustrate a suturing devicefor positioning two suture pairs for forming a total of two stitches atan arteriotomy while the embodiment of FIGS. 14-15 illustrate a suturingdevice for positioning one suture pair for forming a single stitch at anarteriotomy.

More particularly, a suturing device 320 for suturing arterial vesselwalls and other biological tissue is shown in FIGS. 3-13. With initialreference to FIGS. 3, 3A, and 3B, suturing device 320 according to oneembodiment includes first and second needle pairs 356A, 356B and firstand second suture snags 348A, 348B for positioning and capturingrespective ends of first and second suture pairs 360A, 360B beyond theboundaries of the arteriotomy. Suturing device 320 includes an inner orguidewire shaft 340 as well as suture pairs 360A, 360B extendingproximally from a handle 322 and an elongated body 324 extendingdistally from handle 322. Handle 322 includes first and second slidersor actuators 366A, 366B which are utilized to extend needle pairs 356A,356B, respectively, and suture pairs 360A, 360B, respectively, as willbe described in more detail herein, and third and fourth sliders oractuators 368A, 368B which are utilized to deploy suture snags 348A,348B, respectively, as will be described in more detail herein. Moreparticularly, first suture pair 360A and first needle pair 356A areindependently deployed or controlled by first actuator 366A of a firstneedle and suture pair actuation mechanism of handle 322, and secondsuture pair 360B and second needle pair 356B are independently deployedor controlled by opposing second actuator 366B of a second needle andsuture pair actuation mechanism of handle 322. As such, a user maychoose to deploy only one needle pair within a vessel at a time, forexample when the vessel is of a relatively smaller size, or may chooseto deploy both needle pairs simultaneously. In addition, each actuator366A, 366B and corresponding actuation mechanism is provided for thedeployment of two components, i.e., a pair of needles and the respectivesuture pair held thereby, which is beneficial for ease of use.

Elongated body 324 includes an outer shaft 326 and a distal guidingcomponent 332 which is disposed over and coupled to a distal portion ofouter shaft 326. Distal guiding component 332 may be coupled to outershaft 326 by adhesive or a threaded connection, or may be unitary orintegral with the outer shaft. A distal end of distal guiding component332 defines the distal end of elongated body 324. Each of the outershaft and the distal guiding component are hollow tubular components andcollectively define at least one continuous lumen 328 through elongatedbody 324 for housing two elongated transmission members 370A, 370B andinner shaft 340, as shown in the sectional view of FIG. 3B. As will beexplained in more detail herein, transmission members 370A, 370B extendbetween third and fourth actuators 368A, 368B, respectively, and suturesnags 348A, 348B, respectively, and function as actuation mechanisms forthe suture snags because they interact with third and fourth actuators368A, 368B, respectively, in the deployment and retraction of the suturesnags. Inner shaft 340 extends through handle 332 to a tapered distaltip or nosecone 346, which is coupled to a distal end portion 345 (shownin FIG. 4D) of inner shaft 340. Inner shaft 340 and distal tip 346 maydefine a continuous lumen 342 for tracking suturing device 320 over aguidewire (not shown). As shown in the sectional view of FIG. 3A, ahemostasis seal 325 is disposed with handle 322 around inner shaft 340adjacent to a proximal end of outer shaft 326.

Since suturing device 320 is utilized to place the sutures around theborder or edge of an arteriotomy of a vessel, the components of thesuturing device will be described while simultaneously describing amethod of using the suturing device to position suture pairs 360A, 360Bin situ with reference to FIGS. 4-13. Referring to FIG. 4, a side viewof a distal end portion of suturing device 320 having suture pairs 360A,360B loaded therein is shown being distally advanced over a guidewire GWtowards an arteriotomy V_(A) in the vessel wall V_(W) of a vessel. In anembodiment, each suture of suture pairs 360A, 360B is a continuousstrand or filament of material having a first end 362A, 362B,respectively (see FIG. 4E) and a second end 364A, 364B, respectively(see FIG. 3). Exemplary suture materials include but are not limited toa monofilament or plastic suture material, such as polypropylene.Suturing device 320 is in a delivery configuration, in which suturesnags 348A, 348B are in a retracted position while needles pairs 356A,356B and suture pairs 360A, 360B are in a loaded position.

More particularly, as shown in the sectional view of FIG. 4E, two suturesnags 348A, 348B in the collapsed or retracted position are located orhoused in lumen 328 of elongated body 324 and are substantially parallelto a longitudinal axis of elongated body 324. Suture snags 348A, 348Bare disposed within distal guiding component 332 during delivery ofsuturing device 320 so that they do not catch on the vessel walls of thevasculature during insertion and removal of the suturing device. Suturesnags 348A, 348B are deployed by third and fourth actuators 368A, 368B,respectively, on handle 322 that interact with respective suture snagactuation mechanisms within handle 322 comprised of transmission members370A, 370B. Suture snags 348A, 348B are coupled to the actuators viatransmission members 370A, 370B, respectively. With additional referenceto FIG. 4B which is a sectional view of handle 322 at actuators 368A,368B and FIG. 4F which is a perspective view of transmission member 372Bremoved from the suturing device for illustrative purposes only,proximal ends 372A, 372B of transmission members 370A, 370B are locatedadjacent to actuators 368A, 368B, respectively, while distal ends 374A,374B of transmission members 370A, 370B are attached or connected tosuture snags 348A, 348B, respectively. In another embodiment hereof (notshown), transmission members 370A, 370B may be integrally formed withsuture snags 348A, 348B.

Proximal ends 372A, 372B of transmission members 370A, 370B each includea recess or groove 371A, 371B, respectively, that form proximal surfaces375A, 375B and distal surfaces 373A, 373B, respectively. When it isdesired to deploy suture snag 348A, actuator 368A is slid forward ordistally advanced such that a knob or boss 369A thereof slides or moveswithin recess 371A until it abuts against distal surface 373A and pushesor distally advances transmission member 370A, thereby also pushing ordistally advancing suture snag 348A. Similarly, when it is desired todeploy suture snag 348B, actuator 368B is slid forward or distallyadvanced such that a knob or boss 369B thereof slides or moves withinrecess 371B until it abuts against distal surface 373B and pushes ordistally advances transmission member 370B, thereby also pushing ordistally advancing suture snag 348B. In the delivery configuration ofthe suturing device shown in FIGS. 4B and 4E, suture snags 348A, 348Bare both in a retracted position with bosses 369A, 369B of actuators368A, 368B, respectively, abutting against proximal surfaces 375A, 375Bof recesses 371A, 371B of transmission members 370A, 370B, respectively.In addition, actuators 368A, 368B also abut against stops 359A, 359B,respectively, of a housing 323 of the handle 322 that project orprotrude radially to limit proximal retraction of actuators 368A, 368B.

FIG. 4E also illustrates the loaded position of needles pairs 356A, 356Band suture pairs 360A, 360B. Each needle is a generally straight tubularshaft component or hypotube which defines a lumen 357 for slidinglyreceiving a suture and includes a distal end 358 configured to penetrateor pierce through the vessel wall. During delivery, a first suture offirst suture pair 360A has a distal length disposed within a firstneedle of needle pair 356A and a second suture of first suture strandpair 360A has a distal length disposed within a second needle of needlepair 356A, wherein distal ends of the first and second sutures do notextend from the distal ends of their respective needles. Similarly, afirst suture of second suture pair 360B has a distal length disposedwithin a first needle of needle pair 356B and a second suture of secondsuture pair 360B has a distal length disposed within a second needle ofneedle pair 356B, wherein distal ends of the first and second sutures donot extend from the distal ends of their respective needles. Each of thesutures of suture pairs 360A, 360B has a proximal length that extendsproximally of handle 322 to be accessible to a clinician as described inmore detail below. Outer shaft 326 and distal guiding component 332collectively define or include a plurality of needle pathways or guides330 for housing needle pairs 356A, 356B, which are slidingly disposedthereon or therein. With reference to the cross-sectional view of FIG.3B, needle guides 330 may be formed via channels or grooves formed on anexterior surface of outer shaft 326 that mate with a plurality of lumensformed through distal guiding component 332. Alternatively, rather thanchannels or grooves formed on the outer surface thereof, outer shaft 326may define individual lumens for housing each needle.

Needle pair 356A and suture pair 360A are deployed by actuator 366A thatinteract with a first needle and suture actuation mechanism withinhandle 322 comprised of a suture holder 376A, a needle holder 378A, anda carriage 380A. An identical second needle and suture actuationmechanism comprised of a needle holder 378B, a suture holder 376B, and acarriage 380B within handle 322 is utilized to deploy needle pair 356Band suture pair 360B via interaction with actuator 366B. In FIG. 4A,needle pairs 356A, 356B and suture pairs 360A, 360B are each in a loadedposition, with suture pairs 360A, 360B disposed within their respectiveneedle pair 356A, 356B. With reference to FIGS. 4A, 4C, and 4D, needlepair 356A is coupled to needle holder 378A and needle pair 356B iscoupled to needle holder 378B. The needle pairs may be coupled to therespective needle holder via adhesive or other bonding mechanism.Similarly, when in the loaded position, suture pair 360A is coupled to asuture holder 376A which is formed of a resilient material such assilicone. As best shown in the sectional view of FIG. 4G, in the loadedposition of the needle pairs and the suture pairs, proximal ends 331A ofneedle pair 356A are located within a portion of longitudinal slits 327Aof suture holder 376A, adjacent to a distal end 329A of suture holder376A, but at this stage of deployment the needle pair 365A does notextend through the suture holder. In order to couple each suture ofsuture pair 360A to suture holder 376A, each suture of suture pair 360Aextends proximally from a respective proximal end 331A of needle pair356A and extends through a respective longitudinal slit 327A of sutureholder 376A. When suture holder 376A is distally advanced first withneedle holder 378A during deployment of needle pair 365A and seconddecoupled from needle holder 378A during deployment of suture pair 360A,each suture of suture pair 360A is essentially squeezed or held via aninterference fit within its respective slit 327A of suture holder 376Aand therefore is distally advanced or carried by suture holder 376A.Suture pair 360B is similarly coupled to a suture holder 376B which isobscured from the views of FIGS. 4A, 4C, and 4D but may be seen in FIG.8D.

In the delivery configuration of the suturing device, suture holder 376Aand needle holder 378A are both coupled to a shuttle or carriage 380A ofthe actuation mechanism. As will be explained in more detail herein,actuator 366A pushes or distally advances carriage 380A in order tofirst extend or deploy needle pair 356A (via needle holder 378A coupledto carriage 380A) from the suturing device while carrying suture pair360A loaded therein, and thereafter to extend or deploy suture pair 360A(via suture holder 376A which is also coupled to carriage 380A) relativeto and distal of needle pair 356A. Similarly, in the deliveryconfiguration of the suturing device, suture holder 376B and needleholder 378B are both coupled to a shuttle or carriage 380B, and actuator366B pushes or distally advances carriage 380B in order to extend ordeploy first needle pair 356B and then suture pair 360B. Needle holder378A, suture holder 376A, carriage 380A, and actuator 366A are mirrorimages of needle holder 378B, suture holder 376B, carriage 380B, andactuator 3668, respectively, and as such, interactions of the actuationmechanism of needle holder 378A, suture holder 376A, and carriage 380Awith actuator 366A is described herein.

More particularly, carriage 380A includes a first leg 397A, a second leg399A, which extends substantially parallel but spaced apart from firstleg 397A, and a distal bridge 379A, which extends between the distalends of first and second legs 397A, 399A. Each leg 397A, 399A rides orslides along a track 365 of housing 323 of handle 322. Track 365projects radially inward from the housing of the handle, and carriage380A rides or slides along the track as it is distally advanced duringextension of needle pair 356A and/or suture pair 360A as will beexplained in more detail herein. Suture holder 376A is positioned withina proximal portion of carriage 380A, to be sandwiched between first andsecond legs 397A, 399A thereof, and is coupled to carriage 380A viaintegrally formed protrusions 396A of suture holder 376A which extendinto corresponding recesses 394A of first and second legs 397A, 399A.Since suture holder 376A is coupled to carriage 380A, carriage 380Aessentially pulls or carries suture holder 376A, and thus suture pair360A attached thereto, forward when carriage 380A is distally advancedvia actuator 366A. Suture holder 376A includes a longitudinal channel orgroove 381A (see FIG. 4D) formed on an inner surface thereof for slidingor riding along inner shaft 340A.

Needle holder 378A includes a distal portion having claws or prongs382A, a U-shaped proximal portion 384A, and an intermediate portion 388Aextending therebetween. Intermediate portion 388A includes a pair ofchannels or grooves 390A formed on an outer surface thereof forreceiving respective needles of needle pair 356A and also includes achannel or groove 392A (see FIG. 4D) formed on an inner surface thereoffor sliding or riding along inner shaft 340A. In a deliveryconfiguration of the suturing device, needle holder 378A is coupled tocarriage 380A via mating or bearing surfaces 383A (see FIG. 4D). As aresult of the interference fit between needle holder 378A and carriage380A at bearing surfaces 383A, carriage 380A pushes or carries needleholder 378A, and thus needle pair 356A attached thereto, forward, i.e.,in a distal direction, when carriage 380A is distally advanced viaactuator 366A.

Referring to FIG. 5, suturing device 320 is shown advanced to a positionin which a distal portion thereof is positioned through a targetarteriotomy V_(A) such that distal tip 346 is disposed within a lumen ofthe vessel. Suturing device 320 is still in a delivery configuration, inwhich suture snags 348A, 348B are in a retracted position and needlepairs 356A, 356B and suture pairs 360A, 360B are in a loaded position asdescribed above with respect to FIG. 4. Distal guiding component 332includes a stepped or tapered region which creates an abutment surface334. The outer diameter of a proximal portion 333 of distal guidingcomponent 332, i.e., a portion which is proximal to abutment surface334, is greater than the outer diameter of a distal portion 335 ofdistal guiding component 332, i.e., a portion which is distal toabutment surface 334. For example, the outer diameter of proximalportion 333 of distal guiding component 332 may be between 15 and 20French while the outer diameter of distal portion 335 of distal guidingcomponent 332 may be between 8 and 12 French. As shown in FIG. 5, distalportion 335 of distal guiding component 332 is sized to protrude throughthe arteriotomy V_(A) and extend into the lumen of the vessel, whileproximal portion 333 of distal guiding component 332 is sized to abutagainst the outer surface of the vessel wall V_(w) and not protrude orextend through the arteriotomy V_(A) and into the lumen of the vessel.When the user is advancing suturing device 320 to the arteriotomy V_(A),a resistance to further advancement is felt when abutment surface 334contacts the vessel wall, thereby notifying the user that the suturingdevice is in place within the arteriotomy V_(A) as desired.

Once the distal portion of distal guiding component 332 is positionedthrough the arteriotomy V_(A) of the vessel to reside within the lumenof the vessel, suture snags 348A, 348B are deployed against the vesselwall V_(w) around the arteriotomy V_(A) of the vessel as shown in FIG.6. For illustrative purposes, suture snag 348A is shown in FIG. 6C in adeployed configuration removed from the suturing device. Suture snag348B is identical to suture snag 348A and thus only the structure ofsuture snag 348A is described herein. Suture snag 348A includes two arms350A, 352A which are disposed at an angle of approximately 90 degreesrelative to each other. “Approximately” as utilized herein includes arange of plus or minus ten degrees. The proximal ends of arms 350A, 352Aare joined via a connector 354A. Distal ends 374A, 374B of transmissionmembers 370A, 370B may fit within a space or gap 337 between arms 350A,352A to thereby couple transmission members 370A, 370B to suture snag348A, although other mechanisms for coupling the transmission membersand the suture snags may be used. When suturing device 320 is beingdelivered, arms 350A, 352A are generally straight. However, in thedeployed configuration shown in FIG. 60, distal arm portions 351A, 353Aof each arm 350A, 352A, respectively, curve or extend radially outwardfrom a longitudinal axis of the suturing device because at least distalarm portions 351A, 353A are formed from a resilient material having amechanical memory. Mechanical memory may be imparted by thermaltreatment to achieve a spring temper in stainless steel, for example, orto set a shape memory in a susceptible metal alloy, such as nitinol, ora polymer, such as any of the polymers disclosed in U.S. Pat. Appl. Pub.No. 2004/0111111 to Lin, which is incorporated by reference herein inits entirety. Distal arm portions 351A, 353A of suture snag 348A eachinclude a thru-hole or aperture 355 there through. Aperture 355 isgenerally circular or elliptical but includes two radial extensions 339of the aperture or hole that function to catch or grip the ends of thesuture as will be described in more detail herein. As will be shown inan additional embodiment described herein, if a single needle pair and asingle suture snag are included on a suturing device to deploy a singlesuture pair, the distal arm portions of the suture snag arecircumferentially spaced at approximately 180 degrees from each other.However, when two suture snags are included on a suturing device such assuturing device 320, the distal arm portions of each suture snag arecircumferentially spaced approximately 90 degrees from each other.

Distal guiding component 332 includes four passageways or openings 338formed at a distalmost end thereof which allow the distal arm portionsof the two suture snags 348A, 348B to alternate between the retractedposition during delivery in which each suture snag 326 is disposedwithin and is substantially parallel to elongated body 324, as shown anddescribed above with respect to FIGS. 4 and 5, and a second deployedposition in which the distal arm portions of each suture snag 348A, 348Bextend radially outward from openings 338 away from the elongated body,as shown in FIGS. 6, 6A, and 6B. With reference to FIG. 6D which is asectional view of handle 322 at actuators 368A, 368B, when it is desiredto deploy suture snag 348A, actuator 368A is distally advanced such thatboss 369A thereof abuts against distal surface 373A and pushes ordistally advances transmission member 370A, thereby also pushing ordistally advancing distal arm portions 351A, 353A of suture snag 348Aout of two of the four openings 338 of distal guiding component 332.Similarly, when it is desired to deploy suture snag 348B, actuator 368Bis distally advanced such that boss 369B thereof abuts against distalsurface 373B and pushes or distally advances transmission member 370B,thereby also pushing or distally advancing distal arm portions 351B,353B of suture snag 348B out of the other two of the four openings 338of distal guiding component 332. It will be apparent to one of ordinaryskill in the art that suture snags 348A, 348B may be deployedsimultaneously or independently. FIGS. 6A and 6B illustrate both suturesnags 348A, 348B deployed, while FIG. 6E illustrates only suture snag348A deployed. When each suture snag 348A, 348B is distally advanced viaactuator 368A, 368B, respectively, distal arm portions 351A, 353A, 351B,353B extend out of openings 338 formed at a distalmost end of distalguiding component 332. The mechanical memory of each suture snag causesthe distal arm portions 351A, 353A, 351B, 353B to assume their deployedconfigurations and radially extend. When deployed, distal arm portions351A, 353A, 351B, 353B of suture snags 348A, 348B, respectively, lieadjacent to or against an inside surface of the vessel wall V_(w) withrespective apertures 355 thereof positioned radially outward of thearteriotomy V_(A). FIG. 6D illustrates actuators 368A, 368B when bothsuture snags 348A, 348B are in a deployed position with bosses 369A,369B of actuators 368A, 368B, respectively, abutting against distalsurfaces 373A, 373B of recesses 371A, 371B of transmission members 370A,370B, respectively. Proximal ends 372A, 372B of transmission members370A, 370B, respectively, abut against stops 377A, 377B, respectively,of housing 323 of handle 322 which project radially inward to limitdistal advancement of actuators 368A, 368B.

After suture snags 348A, 348B are deployed, needle pair 356A and suturepair 360A are distally advanced until the respective actuation mechanismhas reached a needle deployment position wherein the needles piercethrough the vessel wall V_(w) at points that are radially outward of thearteriotomy V_(A) as shown in FIG. 7. In one embodiment, as shown inFIGS. 7 and 7A, only needle pair 356A is first extended into a lumen ofa vessel. Extending only one needle pair into the vessel at a timeprovides access to relatively smaller vessels. However, it will beunderstood that both needle pairs may alternatively be extended ordeployed into the vessel wall at the same time. With additionalreference to the perspective view of FIG. 7A, needle pair 356A isdistally advanced out of distal ports 336 of distal guiding component332 and is distally advanced through tissue around the arteriotomy of avessel until distal ends 358 of the needles extend through apertures 355of deployed suture snags 348A, 348B. Accordingly, in situ, needle pair356A creates incisions or pathways within tissue around the arteriotomyduring deployment. Although not visible in the views of FIGS. 7 and 7A,suture pair 360A extending within and carried with needle pair 356A issimilarly distally advanced concurrently with needle pair 356A. Notably,since needle pair 356A is distally deployed out of the relatively largerproximal portion of distal guiding component 332, the needles extendstraight out of ports 336 to pierce through the vessel wall V_(W) and donot need to bend or curve. As such, the amount of force or energyrequired to extend the needles is minimized. Further, since no bendingis required, the needles may be formed from stainless steel for improvedpushability. In an embodiment, the outer diameter of the needles rangesbetween 0.015 and 0.025 inches, but needles with other diameters may beused herewith.

In order to extend needle pair 356A and suture pair 360A to the positionshown in FIG. 7, actuator 366A on handle 322 is distally advanced untilthe actuation mechanism associated therewith reaches a needle deploymentposition. With reference to FIG. 7B which is a cutaway view of handle322 at actuator 366A, a knob or boss 367A (shown in phantom) of actuator366A is positioned proximal to and abuts against distal bridge 379A ofcarriage 380A. When actuator 366A is pushed forward or distallyadvanced, boss 367A pushes or distally advances carriage 380A, therebyalso distally advancing in unison both suture holder 376A (and suturepair 360A coupled thereto) and needle holder 378A (and needle pair 356Acoupled thereto). Since suture holder 376A is coupled to carriage 380Avia protrusions 396A which mate with corresponding recesses 394A asdescribed above, carriage 380A pulls or carries suture holder 376A, andthus suture pair 360A attached thereto, forward when carriage 380A isdistally advanced via actuator 366A. In addition, since needle holder378A is coupled to carriage 380A via an interference fit between bearingsurfaces 383A as described above, carriage 380A pushes or carries needleholder 378A, and thus needle pair 356A attached thereto, forward whencarriage 380A is distally advanced via actuator 366A. Needle holder 378Ais carried by or moves concurrently with carriage 380A until U-shapedproximal portion 384A of the needle holder abuts against a stop 385A ofhousing 323 of handle 322, such that the needle deployment position hasbeen reached as shown in FIG. 7B. Needle holder 378A, as well as needlepair 356A attached thereto, cannot be distally advanced after U-shapedproximal portion 384A of the needle holder abuts against stop 385A. Assuch, at this point in the method of use, needle pair 356A is in anextended deployed position while suture pair 360A may be considered tobe in a partially extended position or as remaining in a loaded positionwithin needle pair 356A.

First ends 362A of suture pair 360A are then deployed out of or beyonddistal ends 358 of needle pair 356A as shown in FIGS. 8 and 8A. In orderto extend or deploy suture pair 360A out of needle pair 356A, actuator366A on handle 322 is further distally advanced until the actuationmechanism associated therewith reaches a suture deployment position.With reference to FIGS. 8B and 8C which are cutaway and sectional views,respectively, of handle 322 at actuator 366A, further distal advancementof actuator 366A (shown in phantom in FIG. 8B) results in carriage 380Adisengaging or decoupling from needle holder 378A so that carriage 380Aand suture holder 376A may be further distally advanced. As previouslyexplained, needle holder 378A is prevented from further distal movementbecause U-shaped proximal portion 384A of the needle holder abutsagainst stop 385A of housing 323 of handle 322. With additionalreference back to the sectional view of FIG. 7C, as carriage 380A isfurther distally advanced via actuator 366A, carriage 380A overcomes theinterference fit between bearing surfaces 383A and thereby squeezes orcompresses distal prongs 382A of needle holder 378A to allow thecarriage to slidingly advance over the needle holder. Carriage 380A, aswell as suture holder 376A and suture pair 360A coupled thereto, aredistally advanced via actuator 366A until distal bridge 379A of carriage380A abuts against a stop 386A of housing 323 of handle 322 such thatthe suture deployment position has been reached. As such, suture pair360A is distally advanced relative to needle pair 356A by continuedmovement of actuator 366A. Although the distal advancement of actuator366A is described in two sequential method steps within FIGS. 7 and 8,it will be understood by those of ordinary skill in the art that suchsteps are performed by a single user action, i.e., distal advancement ofactuator 366A.

Carriage 380A rides or slides along track 365 of housing 323 of handle322 as carriage 380A is distally advanced towards stop 386A. Track 365includes a stop 387A that projects radially inward from housing 323 ofhandle 322. When carriage 380A is distally advanced to the point thatdistal bridge 379A abuts against stop 386A, a proximalmost end orsurface of carriage 380A passes over stop 387A such that theproximalmost end or surface of carriage 380A is located distal to stop387A as shown in the sectional view of FIG. 8D. Carriage 380A may bow orarch as it passes or rides over stop 387A, and then snap back to itsflat or planar shape when the proximalmost end or surface of carriage380A is located distal to stop 387A. Stop 387A prevents retraction ofcarriage 380A and suture holder 376A coupled thereto, thereby lockingthe fully extended deployed position of suture pair 360A.

After distal portions of suture pair 360A are extended or deployedbeyond needle pair 356A, needle pair 356A is retracted as shown in FIGS.9 and 9A, thereby leaving only the suture ends extending through thevessel wall and through apertures 355 of deployed suture snag 348A. Withadditional reference to the cutaway and sectional views of FIGS. 9B and9C, respectively, actuator 366A is proximally retracted until boss 367Athereof abuts against U-shaped proximal portion 384A of needle holder378A and then actuator 366A pushes or proximally retracts the needleholder, thereby also proximally retracting needle pair 356A. Carriage380A and suture pair 360A cannot be retracted since they are locked intheir extended positions due to stop 387A, as described above, andneedle holder 378A is free to move independently from and relative tocarriage 380A since it was previously decoupled therefrom. Needle holder378A and needle pair 356A attached thereto are proximally retracteduntil U-shaped proximal portion 384A of the needle holder abuts againstsuture holder 376A, such that the actuation mechanism may be consideredto have reached a needle retraction position as shown in FIGS. 9B and9C. Once needle holder 378A is in its needle retraction position, distaltips 358 of needle pair 356A are retracted back into distal guidingcomponent 332.

In addition, when needle pair 356A is in the retracted position shown inFIGS. 9, 9A, 9B, and 9C, needle pair 356A extends through longitudinalslits 327A of suture holder 376A such that proximal ends 331A of needlepair 356A are located proximal to a proximal end 321A of suture holder376A as best shown in the sectional view of FIG. 9D to envelop orsurround suture pair 360A such that suture pair 360A is slidinglypositioned through needle pair 356A, and therefore is no longer coupledto suture holder 376A. Stated another way, since suture pair 360A isslidably disposed within needle pair 356A for the entire length ofsuture holder 376A, suture pair 360A no longer contacts the sutureholder and therefore is no longer squeezed or held via an interferencefit within longitudinal slits 327A of suture holder 376A. Since needlepair 356A extends through the length of suture holder 376A, suture pair360A disengages from or decouples from suture holder 376A.

As previously mentioned with respect to FIG. 7, it may be desirable toextend only a single needle pair at a time into a lumen of a vessel ifthe vessel is of a relatively smaller size. If only a single needle pairand corresponding suture pair has been deployed into the lumen of thevessel, the remaining needle pair 368B and first ends 362B of suturepair 360B are subsequently extended into the lumen of the vessel viaactuator 366B as shown in FIG. 10 by following the method stepsdescribed above with respect to actuator 366A. Alternatively, suturepair 360B may have been extended into the lumen of the vessel viaactuator 366B before or concurrently with suture pair 360A.

After respective ends of suture pairs 360A, 360B all extend into thelumen of the vessel and both needle pairs 356A, 356B have been retractedinto elongated body 324 of the suturing device, suture snags 348A, 348Bare proximally retracted to thereby capture the four extended sutureends and pull them into suturing device 320 as shown in FIG. 11. Inorder to retract suture snags 348A, 348B, actuators 368A, 368B areproximally retracted until bosses 369A, 369B thereof abut against andpush proximal surfaces 375A, 375B of recesses 371A, 371B of transmissionmembers 370A, 370B. By pushing transmission members 370A, 370B, suturesnags 348A, 348B are thereby pushed or retracted back through openings338 and into distal guiding component 332. Essentially, proximal ends372A, 372B of transmission members 370A, 370B are returned to theposition described above with respect to FIG. 4. Proximal ends 372A,372B of transmission members 370A, 370B are proximally retracted untilbosses 369A, 369B of actuators 368A, 368B, abut against stops 359A,359B, respectively, of housing 323 of handle 322 that project radiallyinward to limit proximal retraction of actuators 368A, 368B. When thesuture snags are retracted, suture pairs 360A, 360B extend out of ports336 of distal guiding component 332, through tissue around thearteriotomy via the pathways or incisions created by needle pairs 356A,356B, and then the ends of suture pairs 360A, 360B are captured withindistal portion 335 of distal guiding component 332 as shown in FIG. 11.When captured, the ends of suture pairs 360A, 360B are pushed intocatches or grips 339 of apertures 355 (see FIG. 6C) and therefore aretightly secured within apertures 355 of the suture snags.

Notably, other suturing devices known in the art utilize extendableneedles to capture modified suture ends of a suture which have beendelivered through an arteriotomy to a position within a vessel lumen.However, suturing device 320 positions ends of a suture through a vesselwall around an arteriotomy and then utilizes deployable suture snags tocapture or catch the suture ends back into the suturing device. As such,suturing device 320 does not require modification of the suture ends forcapture thereof. In addition, suturing device 320 improves consistencyand reliability of capturing the suture ends.

At this point in the method of use, suturing device 320 having thecaptured suture ends therein is retracted until it is withdrawn from apatient so that a clinician gains access to second ends 364A, 364B ofsuture pairs 360A, 360B. More particularly, since suture pairs 360A,360B are no longer coupled to suture holders 376A, 376B, respectively,and are instead slidingly positioned through retracted needle pairs356A, 356B, suture pairs 360A, 360B slide through the needle pairs asthe suturing device 320 (having first ends 362A, 362B captured therein)is retracted until second ends 364A, 364B of the suture pairs exit outof distal ends 358 of needle pairs 356A, 356B. The clinician then tiesor forms at least one surgical knot 363 between the respective secondends of each suture pair, thereby forming a first elongated suture 361Afrom suture pair 360A and a second elongated suture 361B from suturepair 360B. In order to facilitate tying or forming the surgical knotbetween each pair of opposing suture ends, suture pair 360A may beformed from a different color and/or may be a different length thansuture pair 360B so that the physician can easily identify the sutureends that are to be tied together. With reference to FIG. 12, which is atop view of vessel V having an arteriotomy V_(A), newly formed elongatedsutures 361A, 361B extend through the vessel wall around the arteriotomyand the opposing ends thereof (originally first ends 362A, 362B ofsuture pairs 360A, 360B) are still captured within suturing device 320.The clinician then pulls on or further proximally retracts suturingdevice 320 such that surgical knots 363 of elongated sutures 361A, 361Bare positioned over the vessel wall and/or arteriotomy V_(A) as shown inFIG. 12. The physician then cuts or severs elongated sutures 361A, 361Bfrom suturing device 320. The physician may then pull one end of eachelongated suture until surgical knots are accessible, i.e. locatedoutside of the patient. A slip knot (not shown) is then tied below eachsurgical knot 363, and one end of each elongated suture 361A, 361B ispulled to move or slide each slip knot over the length of each elongatedsuture towards arteriotomy V_(A). Hemostasis occurs when each slip knotabuts against the inside of the vessel wall, thereby closing orsubstantially closing the arteriotomy V_(A) with a first stitch 393A anda second stitch 393B as shown in FIG. 13. FIG. 13 illustratesarteriotomy V_(A) closed for illustrative purposes; however, if suturingdevice 320 is being utilized in a pre-closure technique, stitches 393A,393B would seal the arteriotomy V_(A) around an interventional deviceinserted through the arteriotomy V_(A) as would be understood by one ofordinary skill in the art. The method steps described above for formingtwo stitches from suture pairs 360A, 360B are merely exemplary. Otherdevices or methods known in the art may be utilized to form two stitchesfrom suture pairs 360A, 360B after suturing device 320 has captured thesuture ends and thereby positioned the suture pairs through the vesselwall around the arteriotomy as desired. For example, although the abovemethod illustrates forming two essentially parallel stitches 393A, 393Bas shown in FIG. 13, different combinations of sutures may be tiedtogether for forming the stitches, such as opposing sutures located 180degrees from each other, to thereby form two stitches that crisscross inan “X” configuration. Stated another way, the elongated sutures 361A,361B need not be formed from sutures of the same suture pair. Sutures ofsuture pair 360A may be tied to opposing sutures of suture pair 360B.

In order to access smaller vessels, which have inherently smallerarteriotomies due to the relatively smaller diameters of the vesselsthemselves, it may be desirable to utilize a relatively smaller suturingdevice which delivers a single suture pair. FIGS. 14 and 15 illustratean embodiment in which a suturing device 1420 includes a single suturesnag 1448 and a single needle pair 1456 for delivering a single suturepair 1460. FIG. 14 and FIG. 14A are perspective views of a distalportion of suturing device 1420. As shown, suturing device 1420 includesan elongated body 1424 including an outer shaft 1426 and a distalguiding component 1432. Distal guiding component 1432 includes adistally tapered region that ends at an abutment surface 1434, anddistal guiding component 1432 is utilized for guiding needle pair 1456towards deployed suture snag 1448 having radially expandable distal armportions 1451, 1453. A first suture of suture pair 1460 is housed withina first needle of needle pair 1456, and a second suture of suture pair1460 is housed within a second needle of needle pair 1456. FIG. 14Aillustrates first ends 1462 of suture pair 1460 housed within the distalends of needle pair 1456.

FIG. 15 illustrates a sectional view of a handle 1422 of suturing device1420, which deploys a single suture snag 1448 as well as only a singleneedle pair 1456 and single suture pair 1460. FIG. 15A is an enlargedsectional view of actuator 1468 for deploying and retracting suture snag1448. As shown, similar to actuator 368, actuator 1468 includes a knobor boss 1469 which slidingly operates within a recess or groove 1471 ofa proximal end 1472 of a transmission member 1470 which extends to andcouples with a proximal end of suture snag 1448. Actuator 1468 distallyadvances or proximally retracts transmission member 1470, therebydistally advancing or proximally retracting suture snag 1448. FIGS. 15B,15C, and 15D are views of actuator 1466 for extending and retractingneedle pair 1456, as well as for extending suture pair 1460. As shown,similar to actuator 366, actuator 1466 includes a knob or boss 1467which operates to distally advance a shuttle or carriage 1480. In thedelivery configuration of the suturing device, a suture holder 1476 anda needle holder 1478 are both coupled to carriage 1480. Carriage 1480includes a first leg 1497, a second leg 1499, which extendssubstantially parallel but spaced apart from first leg 1497, and adistal bridge 1479 which extends between the proximal ends of first andsecond legs 1497, 1499. Suture holder 1476 is positioned adjacent to andcoupled to a distal portion of carriage 1480, between first and secondlegs 1497, 1499 thereof. Since suture holder 1476 is coupled to carriage1480, carriage 1480 essentially pulls or carries suture holder 1476, andthus suture pair 1460 attached thereto, forward when carriage 1480 isdistally advanced via actuator 1466. Needle holder 1478 includes adistal portion having claws or prongs 1482, which in this embodimentessentially clips or bosses to distal bridge 1479 of carriage 1480.Needle holder 1478 also includes a U-shaped proximal portion 1484A whichincludes a pair of channels or lumens 1490 formed there through forreceiving needle pair 1456 and also includes a channel 1492 formed on aninner surface thereof for sliding or riding along inner shaft 1440. In adelivery configuration of the suturing device, needle holder 1478 iscoupled to carriage 1480 via mating or bearing surfaces 1483 formedbetween prongs 1483 of the needle holder and distal bridge 1479 of thecarriage. As a result of the interference fit between needle holder 1478and carriage 1480 at bearing surfaces 1483, carriage 1480 pushes orcarries needle holder 1478, and thus needle pair 1456 attached thereto,forward when carriage 1480 is distally advanced via actuator 1466 untilthe needle holder abuts against a stop 1485 of a housing 1423 of handle1422. Needle holder 1478, as well as needle pair 1456 attached thereto,cannot be distally advanced any further but continued distal advancementof actuator 1466 results in continued distal advancement of carriage1480, as well as suture holder 1476 and the ends of suture pair 1460. Asbest shown in FIG. 15C, continued distal advancement of carriage 1480results in carriage 1480 overcoming the interference fit between bearingsurfaces 1483 and thereby spreading or pushing apart distal prongs 1482of needle holder 1478, thereby decoupling needle holder 1478 andcarriage 1480 to allow the carriage to slidingly advance through or pastthe needle holder. As such, suture pair 1460 is distally advanced bycontinued movement of actuator 1466 while needle pair 1456 is not.

In another embodiment hereof, in order to access smaller vessels, thesize or outer diameter of the elongated body of the suturing devicesdescribed herein may be minimized by designing the plurality of needlesto bend when being extended out of the distal guiding component. In anembodiment shown in FIG. 16, a suturing device 1620 includes anelongated body 1624 having an outer shaft 1626 and a distal guidingcomponent 1632. Distal guiding component 1632 is utilized for guiding aneedle pair 1656 towards deployed suture snag 1648 having radiallyextendable distal arm portions 1651, 1653. Only one suture snag is showndeployed in FIG. 16, and only one needle is shown for sake of clarityand illustration. In this embodiment, distal guiding component 1632includes a plurality of side openings or ports 1636 in a wall thereofthat each allow the needle associated therewith to be alternatelyextended and retracted therethrough. In a retracted position each needleis disposed within the elongated body and in an extended position eachneedle extends distally and radially outward from a longitudinal axisL_(A) of elongated body 1624. As will be understood by one of ordinaryskill in the art, the number of ports 1636 formed through distal guidingcomponent 1632 corresponds to the number of needles located within theelongated body of suturing device 1620. When each needle pair 1656 isdistally advanced, distal ends 1658 comes into contact with a curveddeflection surface or edge formed within transverse port 1636 thatoperates to guide distal ends 1658 of each needle out of elongated body1624 and causes each needle to bend radially outward at an acute anglerelative to the longitudinal axis L_(A) of elongated body 1624. Asdistal end 1658 exits from transverse port 1636, each needle graduallybends and assumes the extended position shown in FIG. 16 in which eachneedle extends distally and outwardly from elongated body 1624. Inembodiment hereof, the angle θ of the needle deflection may be in arange of between 5 and 25 degrees. When needle pair 1656 is retractedback into elongated body 1624, they return to their original generallystraight configurations since they are no longer in contact with thedeflection surface of distal guiding component 1632 that caused theneedles to bend radially outward in the extended position.

In another embodiment hereof, an inflatable balloon may be utilized asan alternative to suture snags for capturing the ends of the suture(s)beyond the boundaries of the arteriotomy. An inflatable balloon providesa relatively larger target area or zone for placement of the needles ofthe suturing device. In addition, an inflatable balloon may provideapposition to the inner vessel wall during the suturing procedure,thereby improving the structural integrity of the vessel wall for theneedles to puncture or penetrate there through. More particularly, withinitial reference to FIGS. 17 and 17A, suturing device 1720 includesfirst and second needle pairs 1756A, 1756B and an inflatable balloon1810 (shown in FIG. 18) for positioning and capturing respective ends offirst and second suture pairs 1760A, 17608 beyond the boundaries of thearteriotomy. Suturing device 1720 includes a transmission shaft 1770, aswell as suture pairs 1760A, 1760B extending proximally from a handle1722 and an elongated body 1724 extending distally from handle 1722.Handle 1722 includes first and second sliders or actuators 1766A, 1766B(slider 1766B is not shown on the view of FIG. 17 but is located on thehandle similar to slider 366B described above) which each interact witha suture holder, needle holder, and carriage (not shown in FIG. 17 butdisposed within handle 1722) to extend needle pairs 1756A, 1756B,respectively, and suture pairs 1760A, 1760B, respectively, as describedabove with respect to actuators 366A, 366B. Handle 1722 also includes athird slider or actuator 1768 which is utilized to distally advance orextend inflatable balloon 1810 as will be described in more detailherein.

Similar to elongated body 324 described above, elongated body 1724includes an outer shaft 1726 and a distal guiding component 1732 whichis disposed over and coupled to a distal portion of outer shaft 1726.Outer shaft 1726 and distal guiding component 1732 collectively defineor include a plurality of needle pathways or guides 1730 for housingneedle pairs 1756A, 1756B, which are slidingly disposed thereon ortherein. With reference to the cross-sectional view of FIG. 17A, needleguides 1730 may be formed via channels or grooves formed on an exteriorsurface of outer shaft 1726 that mate with a plurality of lumens formedthrough distal guiding component 1732. Alternatively, rather thanchannels or grooves formed on the outer surface thereof, outer shaft1726 may define individual lumens for housing each needle. Each of theouter shaft and the distal guiding component are hollow tubularcomponents and collectively define at least one continuous lumen 1728through elongated body 1724 for housing transmission shaft 1770, asshown in the cross-sectional view of FIG. 17A. Transmission shaft 1770extends through handle 1732 to a tapered distal tip or nosecone 1746,which is coupled to a distal end portion 1745 (shown in FIGS. 18-19) oftransmission shaft 1770.

A distal portion of transmission shaft 1770 is shown removed fromsuturing device 1720 for illustration purposes only in FIGS. 18 and 19.The distal portion of transmission shaft 1770 is positionable through anarteriotomy and includes inflatable balloon 1810, which is shown in adeflated or delivery configuration in FIG. 18 and in an expanded orinflated configuration in FIG. 19. As will be understood by those ofordinary skill in the art, transmission shaft 1770 and balloon 1810collectively form a balloon catheter. A proximal end or neck 1812 and adistal end or neck 1813 of balloon 1810 is coupled to distal end portion1745 of transmission shaft 1770. Proximal and distal necks 1812, 1813 ofballoon 1810 may be joined to transmission shaft 1770 in anyconventional manner known to one of skill in the art of balloon catheterconstruction, such as by laser welding, adhesives, heat fusing, orultrasonic welding. Transmission shown 1770 is a tubular shaft formed bymulti-lumen profile extrusion. Transmission shaft 1770 defines at leastan inflation lumen 1715 and a guidewire lumen 1742 for tracking suturingdevice 1720 over a guidewire GW (shown in FIGS. 18-19). Inflation lumen1715 extends the full length of transmission shaft 1770 to allowinflation fluid received through an inflation port of a hub 1714 (shownin FIG. 17) to be delivered to inflatable balloon 1810. Inflation lumen1715 is in fluid communication with an interior of balloon 1810 via aport or opening (not shown) of transmission shaft 1770 to allowinflation fluid, i.e., saline, to flow between the inflation lumen andthe interior of the balloon. As would be understood by one of ordinaryskill in the art of balloon catheter design, hub 1714 provides a luerhub or other type of fitting that may be connected to a source ofinflation fluid and may be of another construction or configurationwithout departing from the scope of the present invention. In addition,hub 1714 includes a guidewire port (not shown) that communicates withlumen 1742 of transmission shaft 1770 for receiving a guidewire GW therethrough. Transmission shaft 1770 may be formed of a polymeric material,non-exhaustive examples of which include polyethylene, PEBA, polyamideand/or combinations thereof, either blended or co-extruded.

As shown in FIG. 17A, although not required, transmission shaft 1770 mayalso define further lumens in addition to inflation lumen 1715 andguidewire lumen 1742. In the embodiment of FIG. 17A, transmission shaft1770 defines a gas egress lumen 1711 that provides a pathway for gas toexit as balloon 1810 is filled with inflation fluid via inflation lumen1715. Gas egress lumen 1711 is in fluid communication with an interiorof balloon 1810 via a port or opening (not shown) of transmission shaft1770 to allow gas or air to exit from the interior of the balloon intothe gas egress lumen. More particularly, prior to inflation of balloon1810, gas or air may be present within inflation lumen 1715. Duringballoon inflation, such gas gets pushed into the interior volume ofballoon 1810 and creates a trapped gas or air bubble inside the balloon.Such gas bubbles may be released into the blood stream when needle pairs1756A, 1756B are distally advanced or deployed into the balloon, as willbe described in more detail herein. Although small amounts of gas or aircan be introduced into the blood stream without patient injury, it isdesired to minimize the amount of gas that can expel from the balloonafter it is punctured by the needle(s). Thus, gas egress lumen 1711provides a pathway for the gas to travel through during ballooninflation so that the trapped gas bubbles do not form within theinterior of balloon 1810.

As previously mentioned, third slider or actuator 1768 of handle 1722 isutilized to distally advance or extend inflatable balloon 1810. Balloon1810 in its deflated or delivery configuration is disposed or housedwithin distal guiding component 1732 during delivery of suturing device1720 so that it does not catch on the vessel walls of the vasculatureduring insertion and removal of the suturing device. Balloon 1810 isdeployed by third actuator 1768 on handle 1722 that interacts withtransmission shaft 1770, which extends from balloon 1810 and throughhandle 1722. More particularly, third actuator 1768 is coupled totransmission shaft 1770 within handle 1722 so that when it is desired todistally advance balloon 1810, actuator 1768 is slid forward or distallyadvanced to push or distally advance transmission shaft 1770, therebyalso pushing or distally advancing balloon 1810 coupled thereto. Thus,when it is desired to proximally retract balloon 1810, actuator 1768 isslid backward or proximally retracted to pull or proximally retracttransmission shaft 1770, thereby also pulling or proximally retractingballoon 1810.

In the construction of FIG. 17A, transmission shown 1770 is a singleshaft formed by multi-lumen profile extrusion and defines a plurality oflumens there-through. Other types of construction of the transmissionshaft are also amendable to the invention, such as, without limitationthereto, dual concentric shafts. More particularly, as shown in theembodiment of FIG. 17B, an inner shaft 1740 which defines a guidewirelumen 1742B may extend within a transmission shaft 1770B such that anannular inflation lumen 1715B is defined between an inner surface oftransmission shaft 1770B and an outer surface of inner shaft 1740. Aswill be understood by those of ordinary skill in the art, transmissionshaft 1770B, inner shaft 1740, and a balloon (not shown) collectivelyform a balloon catheter having an over-the-wire (OTW) configuration witha proximal end or neck the balloon coupled to a distal end oftransmission shaft 1770B, and a distal end or neck of the balloon iscoupled to a distal end portion of inner shaft 1740. In this embodiment,transmission shaft 1770B and inner shaft 1740 may be coupled together sothat the concentric shafts as well as the balloon are distally advancedand proximally retracted as a single unit or assembly. The concentricshafts may be coupled together via one or more bonds (not shown) whichare non-circumferential so as not to interfere with the flow ofinflation fluid through inflation lumen 1715B.

With reference to the cross-sectional view of FIG. 19A, taken along lineA-A of FIG. 19, in one embodiment hereof, balloon 1810 is a single layerballoon defining a single compartment or interior volume. Balloon 1810may be formed from any material that is relatively elastic anddeformable, including a compliant or semi-compliant material. Ballooncompliance can be defined as the change in balloon diameter and lengthas a function of inflation pressure. A high compliance balloon has arelatively large increase in diameter and length in response to anincrease in inflation pressure, while a balloon having a relativelysmall increase in diameter and length in response to an increase ininflation pressure is said to be a low compliance balloon or anon-compliant balloon. Non-exhaustive examples of materials for balloon1810 include polymers such as silicone, polyethylene, PEBA, polyethyleneterephthalate (PET), polyamide, and polyurethane, copolymers or blendsthereof. In one embodiment, balloon 1810 is a relatively compliantthermoplastic elastomer (TPE) material. The compliant material ofballoon 1810 is self-sealing such that the insertion and removal ofneedles through the balloon material does not affect the operation,i.e., the inflation and deflation, of the balloon. Compliant orsemi-compliant materials such as those listed above as non-exhaustiveexamples of materials for balloon 1810 exhibit self-sealingcharacteristics due to the compliant nature thereof. In general, thecompliance of the material is directly related or proportional to theself-sealing ability of the material such that higher compliancematerials result in more self-sealing characteristics.

In an embodiment hereof, balloon 1810 is pre-blown or pre-formed, i.e.,formed by extruding material into a tube shape and then forming the tubeinto a balloon through a process known as blow molding as will beunderstood by those of ordinary skill in the art of catheter balloonmanufacture. When inflated, pre-formed balloons expand to thepredetermined expanded or inflated shape or diameter of the mold thatwas used in the blow molding process. In another embodiment hereof,balloon 1810 is not pre-formed but rather may be an extruded tubularcomponent that freely expands and deflates back to a tubularconfiguration. As used herein, “freely expands” refers to uncontrolledexpansion of the balloon rather than expansion to a predeterminedexpanded or inflated shape of the mold that was used in the blow moldingprocess. The inflated or expanded configuration of a non pre-formedballoon is generally spherical and may be similar to that of apre-formed balloon, however, such expansion is less controlled and theouter diameter thereof is less predictable. Such a non pre-formedballoon may be deflated via retraction or removal of the needles of thesuturing device, and thus does not require a vacuum to cause deflationthereof. More particularly, when the needles of suturing device 1720 areproximally retracted as described in more detail herein, removal of theneedles causes the non pre-formed balloon to deflate or revert back toits tubular deflated or delivery configuration due to the elastic natureof the balloon. As the non pre-formed balloon deflates, the inflationfluid, i.e., saline, leaks out of the holes formed by needle pairs1756A, 1756B. Although a vacuum is not required to cause deflation of anon pre-formed balloon, it will be apparent to one of ordinary skill inthe art that a vacuum may be applied to accelerate deflation of theballoon.

In embodiments hereof, the balloon may include dual or double layers ofdifferent materials and/or may include multiple compartments orchambers. For example, as illustrated in FIG. 20 in another embodimenttaken along line A-A of FIG. 19, a balloon 2010 includes an outer layer2016 and an inner layer 2018. Outer layer 2016 is formed from acompliant or semi-compliant material that is self-sealing, such as thoselisted above with respect to balloon 1810, while inner layer 2018 isformed from a non-compliant or low-compliant material such as but notlimited to polyethylene terephthalate, or nylon-based non-compliantmaterials such as Grilamid™ or Vestamid™. Since non-compliant materialsgenerally expand more predictably than compliant materials and have ahigher tensile strength than compliant materials, the addition ofnon-compliant inner layer 2018 allows balloon 2010 to be pre-blown orpre-formed to a predetermined inflated or expanded diameter whilecompliant outer layer 2016 provides the self-sealing function.

Balloons having multiple compartments or chambers are illustrated inFIGS. 21-22, other embodiments taken along line A-A of FIG. 19. FIG. 21illustrates a single layer balloon 2110 having four internalcompartments 2117A, 2117B, 2117C, 2117D, collectively referred to ascompartments 2117. Four compartments 2117 correspond to the four needlesof needle pairs 1756A, 1756B. Multiple compartments 2117 ensure that ifany leakage of inflation fluid occurs when a needle pierces into itsrespective compartment, the leakage would be confined to a singlechamber of the balloon and pressure may be maintained in thenon-affected compartments. In addition, multiple compartments 2117 arebeneficial when needle pairs 1756A, 1756B are deployednon-simultaneously because each compartment is individually inflatableas described in more detail herein and may be selectively inflatedimmediately prior to deployment of the corresponding needle pair.Balloon 2110 is formed from a compliant or semi-compliant material thatis self-sealing, such as those listed above with respect to balloon1810. FIG. 22 illustrates a dual layer balloon 2210 having fourcompartments 2217A, 2217B, 2217C, 2217D. Balloon 2210 includes an outerlayer 2216 and an inner layer 2218. Outer layer 2216 is formed from acompliant or semi-compliant material that is self-sealing, such as thoselisted above with respect to balloon 1810, while inner layer 2218 isformed from a non-compliant or low-compliant material such as but notlimited to polyethylene terephthalate. If the suturing device includes aballoon having multiple internal compartments, i.e., balloon 2110 orballoon 2210, transmission shaft 2370 as shown in FIG. 23 defines aplurality of individual inflation lumens 2319A, 2319B, 2319C, 2319Dextending there-through rather than a single inflation lumen such thatinflation and deflation of each individual compartment of the balloonmay be separately and selectively controlled. Thus, each chamber orcompartment of the balloon is independently inflatable.

FIGS. 24-32 illustrate a method of using suturing device 1720 in orderto position two sutures at an arteriotomy of a vessel wall of a vessel.Referring to FIG. 24, suturing device 1720 is shown advanced to aposition in which a distal portion thereof is positioned through atarget arteriotomy V_(A) such that distal tip 1746 is disposed within alumen of the vessel. Suturing device 1720 is in a deliveryconfiguration, in which inflatable balloon 1810 is in a deflatedconfiguration and disposed within the elongated body of the suturingdevice. In addition, needle pairs 1756A, 1756B and suture pairs 1760A,1760B are in a loaded position described above with respect to FIGS. 4and 17. Similar to distal guiding component 332, distal guidingcomponent 1732 includes a stepped or tapered region which creates anabutment surface 1734. As shown in FIG. 24, a distal portion 1735 ofdistal guiding component 1732 is sized to protrude through thearteriotomy V_(A) and extend into the lumen of the vessel, while aproximal portion 1733 of distal guiding component 1732 is sized to abutagainst the outer surface of the vessel wall V_(W) and not protrude orextend through the arteriotomy V_(A) and into the lumen of the vessel.When the user is advancing suturing device 1720 to the arteriotomyV_(A), a resistance to further advancement is felt when abutment surface1734 contacts the vessel wall, thereby notifying the user that thesuturing device is in place within the arteriotomy V_(A) as desired.

Once the distal portion of distal guiding component 1732 is positionedthrough the arteriotomy V_(A) of the vessel to reside within the lumenof the vessel, transmission shaft 1770, and balloon 1810 coupled theretoare distally advanced such that balloon 1810 exits from a distalmostopening of distal guiding component 1732 and is positioned within thelumen of the vessel as shown in FIG. 25. While being distally advancedor extended into position, balloon 1810 remains in its deflated ordelivery configuration. When it is desired to distally advance or extendballoon 1810, actuator or slider 1768 of handle 1722 is distallyadvanced such that the actuator pushes or distally advances transmissionshaft 1770 as described above.

Next, balloon 1810 is inflated within the lumen of the vessel to aninflated or expanded configuration as shown in FIG. 26. Moreparticularly, a source of inflation fluid is connected to the inflationport of hub 1714 so that balloon 1810 may be inflated as is known to oneof ordinary skill in the art. In an embodiment hereof, the inflationfluid may be saline. In another embodiment hereof, the inflation fluidmay be a contrast fluid to assist in visualization of balloon 1810 insitu. When inflated, balloon 1810 radially expands and extends away fromthe elongated body of the suturing device. Balloon 1810 may lie againstan inside surface of the vessel wall V_(w) or be slightly spaced apartfrom the vessel wall, with the balloon outer surface positioned radiallyoutward of the arteriotomy V_(A). As such, balloon 1810 providesapposition to vessel wall V_(w) during the suturing procedure, therebyimproving the structural integrity of vessel wall when needle pairs1756A, 1756B are distally advanced to penetrate through the vessel walland through inflated balloon 1810 as described in more detail below.

After balloon 1810 is inflated, needle pair 1756A and suture pair 1760Aare distally advanced or extended to a deployed position in which needlepair 1756A and suture pair 1760A distally extend from a distal end ofthe elongated body of the suturing device and penetrate through thevessel wall and through inflated balloon 1810. More particularly, asshown in FIG. 27, needle pair 1756A and suture pair 1760A are distallyadvanced until the respective actuation mechanism has reached a needledeployment position wherein the needles pierce through the vessel wallV_(w) and extend into balloon 1810. Accordingly, in situ, needle pair1756A creates incisions or pathways within tissue around the arteriotomyduring deployment. In one embodiment, as shown in FIG. 27, only needlepair 1756A is first extended into a lumen of a vessel although, as inthe embodiment described above with respect to FIGS. 3-13, it will beunderstood that both needle pairs may alternatively be extended ordeployed into the vessel wall at the same time. Although not visible inthe view of FIG. 27, suture pair 1760A extending within and carried withneedle pair 1756A is similarly distally advanced concurrently withneedle pair 1756A. In order to extend needle pair 1756A and suture pair1760A to the position shown in FIG. 27, actuator 1766A on handle 1722 isdistally advanced until the actuation mechanism associated therewithreaches a needle deployment position as described above with respect toactuator 366A. As previously stated, balloon 1810 is formed from acompliant material that is self-sealing such that the material sealsaround the needles when the needles penetrate into the inflated balloon.Thus, the insertion and removal of needles through the balloon materialdoes not affect the operation, i.e., the inflation and deflation, of theballoon.

First ends 1762A of suture pair 1760A are then deployed out of or beyonddistal ends 1758 of needle pair 1756A as shown in FIG. 28. In order toextend or deploy suture pair 1760A out of needle pair 1756A, actuator1766A on handle 1722 is further distally advanced until the actuationmechanism associated therewith reaches a suture deployment position asdescribed with respect to actuator 366A above. As such, suture pair1760A is distally advanced relative to needle pair 1756A by continuedmovement of actuator 1766A. Although the distal advancement of actuator1766A is described in two sequential method steps within FIGS. 27 and28, it will be understood by those of ordinary skill in the art thatsuch steps are performed by a single user action, i.e., distaladvancement of actuator 1766A.

After distal portions of suture pair 1760A are extended or deployedbeyond needle pair 1756A, needle pair 1756A is retracted as shown inFIG. 29, thereby leaving only the suture ends extending through thevessel wall and within an interior volume of inflated balloon 1810.Needle pair 1756A is retracted and suture pair 1760A remains extended ordeployed via operation of actuator 1766A, as described with respect toactuator 366A above.

As previously mentioned with respect to FIG. 27, it may be desirable toextend only a single needle pair at a time into a lumen of a vessel ifthe vessel is of a relatively smaller size. If only a single needle pairand corresponding suture pair has been deployed into the lumen of thevessel, the remaining needle pair 1768B and first ends 1762B of suturepair 1760B are subsequently extended into the lumen of the vessel viaactuator 1766B as shown in FIG. 30 by following the method stepsdescribed above with respect to actuator 1766A. Alternatively, suturepair 1760B may have been extended into the lumen of the vessel viaactuator 17668 before or concurrently with suture pair 1760A.

After respective ends of suture pairs 1760A, 1760B all extend into thelumen of the vessel and both needle pairs 1756A, 1756B have beenretracted into elongated body 1724 of the suturing device, balloon 1810is deflated to thereby capture the four extended suture ends into theballoon as shown in FIG. 31. More particularly, in order to capture theextended suture ends, balloon 1810 deflates and holes formed by theretracted needle pairs compress over or around the sutures. In oneembodiment hereof in which balloon 1810 is a pre-formed or pre-blownballoon, a vacuum (not shown) may be applied to hub 1714 in order toremove the inflation fluid from the interior of balloon 1810 and deflateballoon 1810, to as would be understood by one of ordinary skill in theart. When the vacuum is applied and the balloon deflates, the sutureends are compacted, packed, or otherwise clamped within the compressedinterior volume of the balloon. In another embodiment hereof in whichballoon 1810 is not a pre-formed or pre-blown balloon, the use of avacuum to deflate balloon 1810 may not be required as described in moredetail above. If a vacuum is not applied to deflate the balloon, theinflation fluid leaks out of the holes formed by needle pairs 1756A,1756B as the balloon reverts or returns to its deflated or deliveryconfiguration.

Once balloon 1810 is deflated with the suture ends captured therein,transmission shaft 1770 and balloon 1810 are proximally retracted untilballoon 1810 is positioned within distal guiding component 1732 and/orelongated body 1724 of the suturing device as shown in FIG. 32, therebypulling the captured first ends of the sutures into the suturing device.In order to proximally retract deflated balloon 1810, actuator or slider1768 of handle 1722 is proximally retracted such that the actuator pullsor proximally retracts transmission shaft 1770 as described above. Whenballoon 1810 is disposed within the elongated body of the suturingdevice, suture pairs 1760A, 1760B extend out of ports 1736 of distalguiding component 1732, through tissue around the arteriotomy V_(A) viathe pathways or incisions created by needle pairs 1756A, 1756B, and thenthe ends of suture pairs 1760A, 1760B are captured within distal portion1735 of distal guiding component 1732 as shown in FIG. 32. The frictionbetween deflated balloon 1810 and the inner surface of the distalguiding component 1732 secures or locks the ends of the sutures withinthe distal guiding component. In addition, when transmission shaft 1770is retracted, tapered distal tip or nosecone 1746 is adjacent to orabuts against the distalmost end of distal guiding component 1732 tooperate as a plug or stop that tightly secures the ends of the sutureswithin the distal guiding component. At this point in the method of use,suturing device 1720 having the captured suture ends therein isretracted until it is withdrawn from a patient so that a clinician gainsaccess to the second or non-captured suture ends in the same manner asdescribed above with respect to suturing device 320. Once a clinicianhas gained access to the second suture ends, at least one surgical knotmay be tied or formed between the respective second ends of each suturepair to form two elongated sutures that may be manipulated to close orsubstantially close the arteriotomy V_(A) in the same manner asdescribed above with respect to FIGS. 12-13 and suturing device 320.

In another embodiment hereof, the suturing device may include anexpandable suture capture or snare component as an alternative forcapturing the ends of the suture(s) beyond the boundaries of thearteriotomy. An expandable suture capture or snare component provides arelatively larger target area or zone for placement of the needles ofthe suturing device and, if desired, may be configured to provideapposition to the inner vessel wall during the suturing procedure,thereby improving the structural integrity of the vessel wall for theneedles to puncture or penetrate there through. For example, a suturingdevice 3320 having a distal guiding component 3332 of an elongated body3324, a transmission shaft 3370, an inner shaft 3340, and expandablesuture capture component 3308 is illustrated in FIGS. 33-34, withexpandable suture capture component 3308 in a delivery or compressedconfiguration in FIG. 33 and in a deployed or expanded configuration inFIG. 34. Only a distal portion of suturing device 3320 is shown in FIGS.33-34, but it will be understood that by those of ordinary skill in theart that transmission shaft 3370, inner shaft 3340, and expandablesuture capture component 3308 may replace transmission shaft 1770 andinflatable balloon 1810 of suturing device 1720. A proximal end 3309 ofexpandable suture capture component 3308 is coupled to a distal end 3311of a transmission shaft 3370. Proximal end 3309 of expandable suturecapture component 3308 may be spot welded, laser welded or secured usinga bonding sleeve or adhesive to transmission shaft 3370 as would beapparent to one skilled in the relevant art. Inner shaft 3340 having atapered distal tip 3346 coupled to a distal end thereof extends throughtransmission shaft 3370 and expandable suture capture component 3308.

Expandable suture capture component 3308 is formed from a self-expandingmaterial meaning it has a mechanical memory to return to the expanded ordeployed configuration of FIG. 34. Mechanical memory may be imparted toexpandable suture capture component 3308 by thermal treatment to achievea spring temper in stainless steel, for example, or to set a shapememory in a susceptible metal alloy, such as Nitinol. In the delivery orcompressed configuration, expandable suture capture component 3308 is arelatively straight cylindrical or tubular structure disposed withindistal guiding component 3332 and/or elongated body 3324. The deliveryor compressed configuration provides expandable suture capture component3308 with a minimized delivery profile such that suturing device 3320may be advanced to the target site. When it is desired to deployexpandable suture capture component 3308, expandable suture capturecomponent 3308 is distally advanced until it is no longer disposedwithin distal guiding component 3332 and/or elongated body 3324. Onceexpandable suture capture component 3308 is no longer constrained, itassumes the deployed or expanded configuration of FIG. 34 and radiallyexpands and extends away from distal guiding component 3332 and/orelongated body 3324. An expanded or deployed outer diameter ofexpandable suture capture component 3308 may vary according toapplication. In one embodiment, the expanded or deployed outer diameterof expandable suture capture component 3308 is predetermined to besmaller than an inner diameter of the target vessel, i.e., a diameter ofthe vessel lumen. In another embodiment, the expanded or deployed outerdiameter of expandable suture capture component 3308 is predetermined tobe equal to or slightly greater than the inner diameter of the targetvessel. Stated another way, the expanded or deployed outer diameter ofexpandable suture capture component 3308 is predetermined to beover-sized with respect to the inner diameter of the target vessel suchthat when deployed, radially expandable suture capture component 3308slightly over-expands the vessel and provides apposition to the innervessel wall during the suturing procedure, thereby improving thestructural integrity of the vessel wall for the needles to puncture orpenetrate there through.

Expandable suture capture component 3308 includes a tubular braided ormesh structure 3306 that is expandable within a vessel at a treatmentsite of an arteriotomy. Open spaces 3307 in braided or mesh tubularstructure 3306 allow blood or other fluid to flow there-through, suchthat the blood vessel is not blocked or occluded. In an embodiment,expandable suture capture component 3308 is a tubular braided structureconstructed from a plurality of self-expanding metallic wires orfilaments woven together to form a tubular or cylindrical structure. Inanother embodiment, expandable suture capture component 3308 may beconstructed from a stamped metallic mesh of self-expanding material. Inan embodiment hereof, the mesh pore size is 1000 microns. However, withrespect to a minimum mesh pore size, the only requirement is that themesh pore size may allow a needle to pass there-through. Similarly, withrespect to a maximum pore size, the only requirement is that the meshpore size captures a suture therein when collapsed. Thus, the mesh poresize can vary for example from 50 to 5000 microns. In addition to thesize of open spaces 3307 or the mesh pore size, the flexibility and/orstrength of expandable suture capture component 3308 may be tailored bycontrolling the diameter or thickness of the wire utilized in braided ormesh tubular structure 3306 or the thickness of the stamped metallicmesh, respectively. In general, smaller diameters and thicknesses resultin a more flexible expandable suture capture component 3308 thatconforms and bends to the native anatomy while larger diameters andthicknesses result in a stronger, stiffer expandable suture capturecomponent 3308 that more precisely retains the expanded or deployedconfiguration in situ. In addition, pics per inch, or the number ofwinds in each braid per inch thereof, may be varied to tailor thecharacteristics of expandable suture capture component 3308. In anembodiment hereof, increasing the height and decreasing the width of thenumber of winds in each braid may more effectively capture or snare thesutures extending therein when expandable suture capture component 3308is collapsed as described in more detail herein.

The deployed configuration of expandable suture capture component 3308is cylindrical. However, the expandable suture capture component mayhave other deployed configurations that are operable to capture sutureends. For example, FIG. 35 illustrates an expandable suture capturecomponent 3508 having a cone-shaped deployed or expanded configurationand FIG. 36 illustrates an expandable suture capture component 3608having a disc-shaped deployed or expanded configuration. In addition,FIG. 36A illustrates an expandable suture capture component 3608A havinga disc-shaped deployed or expanded configuration that is angled withrespect to the longitudinal axis of the suturing device. Moreparticularly, the suturing device may be introduced into a vessel havinga vessel wall VW at an acute angle θ. In one embodiment, acute angle θis between 30 and 45 degrees but may range between 30 and 89 degrees.When deployed or expanded, disc-shaped expandable suture capturecomponent 3608A is angled with respect to the suturing device tocompensate or accommodate for the angled introduction into the vesseland permit disc-shaped expandable suture capture component 3608A to liesubstantially flat against or parallel to the vessel wall VW of thevessel. As such, when deployed, a longitudinal axis L_(AM) ofdisc-shaped expandable suture capture component 3608A forms acute angleθ with a longitudinal axis L_(AD) of the suturing device. Other deployedconfigurations are suitable for use herein, such as but not limited to aspherical or ellipsoidal deployed configuration.

FIGS. 37-38 illustrate another embodiment of an expandable suturecapture component for capturing the ends of the suture(s) beyond theboundaries of the arteriotomy. A suturing device 3720 having a distalguiding component 3732 of an elongated body 3724, a transmission shaft3770, an inner shaft 3740, and expandable suture capture component 3708is illustrated in FIGS. 37-38, with expandable suture capture component3708 in a delivery or compressed configuration in FIG. 37 and in adeployed or expanded configuration in FIG. 38. Inner shaft 3740 having atapered distal tip 3746 coupled to a distal end thereof extends throughtransmission shaft 3770 and expandable suture capture component 3708.

Similar to expandable suture capture component 3308, expandable suturecapture component 3708 is formed from a self-expanding material meaningit has a mechanical memory to return to the expanded or deployedconfiguration of FIG. 38. However, in this embodiment, expandable suturecapture component 3708 includes a plurality of overlapping or overlayingloops 3704. In the delivery or compressed configuration, loops 3704 ofexpandable suture capture component 3708 are compressed together anddisposed within distal guiding component 3732 and/or elongated body3724. When it is desired to deploy expandable suture capture component3708, expandable suture capture component 3708 is distally advanceduntil it is no longer disposed within distal guiding component 3732and/or elongated body 3724. Once expandable suture capture component3708 is no longer constrained, it assumes the deployed or expandedconfiguration of FIG. 38 and the plurality of loops 3704 radially expandand extend away from distal guiding component 3732 and/or elongated body3824.

The method for utilizing expandable suture capture components 3308, 3708for capturing the ends of the suture(s) beyond the boundaries of thearteriotomy is similar to the method for utilizing inflatable balloon1810 described with respect to FIGS. 24-32. More particularly, FIGS.39-45 illustrate a method of using suturing device 3320 in order toposition two sutures at an arteriotomy of a vessel wall of a vessel.Referring to FIG. 39, suturing device 3320 is shown advanced to aposition in which a distal portion thereof is positioned through atarget arteriotomy V_(A) such that distal tip 3346 is disposed within alumen of the vessel. Suturing device 3320 is in a deliveryconfiguration, in which expandable suture capture component 3308 is in adelivery configuration and disposed within the elongated body of thesuturing device. In addition, needle pairs 3356A, 3356B and suture pairs3360A, 3360B are in a loaded position as described above with respect toprevious embodiments. Similar to distal guiding component 332, distalguiding component 3332 includes a stepped or tapered region whichcreates an abutment surface 3334 that contacts the vessel wall, therebynotifying the user that the suturing device is in place within thearteriotomy V_(A) as desired.

Once the distal portion of distal guiding component 3332 is positionedthrough the arteriotomy V_(A) of the vessel to reside within the lumenof the vessel, transmission shaft 3370 and expandable suture capturecomponent 3308 coupled thereto are distally advanced or extended intothe lumen of the vessel. When expandable suture capture component 3308is released from distal guiding component 3332, it self-expands to itsdeployed configuration in which the expandable suture capture componentradially expands and extends away from the elongated body as shown inFIG. 40. Expanded suture capture component 3308 may lie against aninside surface of the vessel wall V_(w) or be slightly spaced apart fromthe vessel wall, with the component's outer surface positioned radiallyoutward of the arteriotomy V_(A). As such, expandable suture capturecomponent 3308 provides apposition to vessel wall V_(w) during thesuturing procedure, thereby improving the structural integrity of vesselwall when needle pairs 3356A, 3356B are distally advanced to penetratethrough the vessel wall and through expanded suture capture component3308 as described in more detail below.

After expandable suture capture component 3308 is deployed or expanded,needle pair 3356A and suture pair 3360A are distally advanced orextended to a deployed position in which needle pair 3356A and suturepair 3360A distally extend from a distal end of the elongated body ofthe suturing device and penetrate through the vessel wall and throughexpanded suture capture component 3308. More particularly, as shown inFIG. 41, needle pair 3356A and suture pair 3360A are distally advanceduntil the respective actuation mechanism has reached a needle deploymentposition wherein the needles pierce through the vessel wall V_(w) andextend into the open spaces of the braided or mesh tubular structure ofexpanded suture capture component 3308. Accordingly, in situ, needlepair 3356A creates incisions or pathways within tissue around thearteriotomy during deployment. In one embodiment, as shown in FIG. 41,only needle pair 3356A is first extended into a lumen of a vesselalthough, as in the embodiment described above with respect to FIGS.3-13, it will be understood that both needle pairs may alternatively beextended or deployed into the vessel wall at the same time. However, inthis embodiment, unlike previous embodiments described herein,non-simultaneous deployment of the needle pairs is not required toaccommodate smaller vessel sizes since expandable suture capturecomponent 3308 expands to its expanded or deployed configuration withinthe vessel lumen and accommodates a range of vessel sizes. Although notvisible in the view of FIG. 41, suture pair 3360A extending within andcarried with needle pair 3356A is similarly distally advancedconcurrently with needle pair 3356A.

First ends 3362A of suture pair 3360A are then deployed out of or beyonddistal ends 3358 of needle pair 3356A as shown in FIG. 42. In order toextend or deploy suture pair 3360A out of needle pair 3356A, theactuator or slider associated therewith is further distally advanceduntil it reaches a suture deployment position as described with respectto actuator 366A above. As such, suture pair 3360A is distally advancedrelative to needle pair 3356A by continued movement of the actuatorassociated therewith.

After distal portions of suture pair 3360A are extended or deployedbeyond needle pair 3356A, needle pair 3356A is retracted as shown inFIG. 43, thereby leaving only the suture ends extending through thevessel wall and within an interior volume of expanded suture capturecomponent 3308. Needle pair 3356A is retracted and suture pair 3360Aremains extended or deployed via operation of the actuator or sliderassociated therewith, as described with respect to actuator 366A above.

As previously mentioned with respect to FIG. 41, it may be desirable toextend only a single needle pair at a time into a lumen of a vessel ifthe vessel is of a relatively smaller size. If only a single needle pairand corresponding suture pair has been deployed into the lumen of thevessel, the remaining needle pair 3368B and first ends 3362B of suturepair 3360B are subsequently extended into the lumen of the vessel viathe actuator or slider associated therewith as shown in FIG. 44 byfollowing the method steps described above for needle pair 3368A andsuture pair 3360A. Alternatively, suture pair 3360B may have beenextended into the lumen of the vessel via the actuator or sliderassociated therewith before or concurrently with suture pair 3360A.

After respective ends of suture pairs 3360A, 3360B all extend into thelumen of the vessel and both needle pairs 3356A, 3356B have beenretracted into elongated body 3324 of the suturing device, transmissionshaft 3370 and expandable suture capture component 3308 coupled theretoare proximally retracted back into distal guiding component 3332 and/orelongated body 3324 of the suturing device, thereby collapsing theexpandable suture capture component to the compressed configuration andpulling the four extended suture ends into the elongated body of thesuturing device as shown in FIG. 45. More particularly, in order tocapture the extended suture ends, the suture ends are ensnared ortrapped within the compressed interior volume of suture capturecomponent 3308 when the suture capture component is pulled into theelongated body of the suturing device. When suture capture component3308 is disposed within the elongated body of the suturing device,suture pairs 3360A, 3360B extend out of ports 3336 of distal guidingcomponent 3332, through tissue around the arteriotomy V_(A) via thepathways or incisions created by needle pairs 3356A, 3356B, and then theends of suture pairs 3360A, 3360B are captured within distal guidingcomponent 3332. The friction between compressed suture capture component3308 and the inner surface of the distal guiding component 3332 securesor anchors the ends of the sutures within the distal guiding component.In addition, tapered distal tip or nosecone 3346 is adjacent to or abutsagainst the distalmost end of distal guiding component 3332 to operateas a plug or stop that tightly secures the ends of the sutures withinthe distal guiding component. At this point in the method of use,suturing device 3320 having the captured suture ends therein isretracted until it is withdrawn from a patient so that a clinician gainsaccess to the second or non-captured suture ends in the same manner asdescribed above with respect to suturing device 320. Once a clinicianhas gained access to the second suture ends, at least one surgical knotmay be tied or formed between the respective second ends of each suturepair to form two elongated sutures that may be manipulated to close orsubstantially close the arteriotomy V_(A) in the same manner asdescribed above with respect to FIGS. 12-13 and suturing device 320.

The expandable suture capture components described herein self-expand totheir deployed or expanded configurations upon release or exit from thesuturing device. However, it will be understood by one of ordinary skillin the art that deployment or expansion of the expandable suture capturecomponents may be accomplished via other mechanisms. For example,expandable suture capture components may be coupled to both thetransmission shaft and the inner or guidewire shaft, and expansionthereof may be accomplished via relative motion between the shafts. Moreparticularly, a transmission shaft 4670, an inner shaft 4640, andexpandable suture capture component 4608 is illustrated in FIGS. 46-47,with expandable suture capture component 4608 in a delivery or collapsedconfiguration in FIG. 46 and in a deployed or expanded configuration inFIG. 47. Only a distal portion of transmission shaft 4670 and innershaft 4640 are shown in FIGS. 46-47, but it will be understood that bythose of ordinary skill in the art that transmission shaft 4670, innershaft 4640, and expandable suture capture component 4608 may replacetransmission shaft 3370, inner shaft 3340, and expandable suture capturecomponent 3308 of suturing device 3320. A proximal end 4609 ofexpandable suture capture component 4608 is coupled to a distal end 4611of transmission shaft 4670. Inner shaft 4640 having a tapered distal tip4646 coupled to a distal end thereof extends through transmission shaft4670 and expandable suture capture component 4608. A distal end 4605 ofexpandable suture capture component 4608 is coupled to inner shaft 4640,proximal to tapered distal tip 4646. Expandable suture capture component4608 may be spot welded, laser welded or secured using a bonding sleeveor adhesive to transmission shaft 4670 and inner shaft 4640 as would beapparent to one skilled in the relevant art.

Expandable suture capture component 4608 is expanded and contracted byrelative movement between inner shaft 4640 and transmission shaft 4670.While inner shaft 4640 remains stationary or fixed, transmission shaft4670 and expandable suture capture component 4608 coupled thereto aredistally advanced over inner shaft 4640. When transmission shaft 4670 isdistally advanced, the attachment point or bond between expandablesuture capture component 4608 and inner shaft 4640 remains fixed suchthat expandable suture capture component 4608 radially expands to thebulbous or spherical deployed configuration shown in FIG. 47. Similarly,when transmission shaft 4670 and expandable suture capture component4608 coupled thereto are proximally retracted over inner shaft 4640,expandable suture capture component 4608 collapses or straightens backto the delivery configuration of FIG. 46. Although described withtransmission shaft 4670 being movable relative to inner shaft 4640 toexpand expandable suture capture component 4608, it should be apparentto one of ordinary skill in the art that expandable suture capturecomponent 4608 is expanded by shortening the distance between proximaland distal ends 4609, 4605 thereof. Thus, in another embodiment,expandable suture capture component 4608 may be expanded by proximallyretracting inner shaft 4640 while holding transmission shaft 4670stationary. In addition, expandable suture capture component 4608 may beexpanded by a combination of distally advancing transmission shaft 4670and proximally retracting inner shaft 4640.

When expansion of expandable suture capture component 4608 isaccomplished via relative motion between the transmission shaft andinner shaft, the expandable suture capture component may be constructedfrom polymeric materials that are less traumatic than the metallicself-expanding materials that are utilized for expandable suture capturecomponent 3308. In addition, when expansion of expandable suture capturecomponent 4608 is accomplished via relative motion between thetransmission shaft and inner shaft, the outer expanded or deployeddiameter of the expandable suture capture component may be selectivelycontrolled or varied in situ. For example, expandable suture capturecomponent 4608 may be expanded to be selectively over-sized with respectto the inner diameter of the target vessel such that when deployed,radially expandable suture capture component 4608 slightly over-expandsthe vessel and provides apposition to the inner vessel wall during thesuturing procedure, thereby improving the structural integrity of thevessel wall for the needles to puncture or penetrate there through.

FIG. 48 illustrates another embodiment of an expandable suture capturecomponent 4808 having dual mesh layers 4803A, 4803B. More particularly,a transmission shaft 4870, an inner shaft 4840, and expandable suturecapture component 4808 is illustrated in FIG. 48, with expandable suturecapture component 4808 in a deployed or expanded configuration in FIG.48. Only a distal portion of transmission shaft 4870 and inner shaft4840 are shown in FIG. 48, but it will be understood that by those ofordinary skill in the art that transmission shaft 4870, inner shaft4840, and expandable suture capture component 4808 may replacetransmission shaft 3370, inner shaft 3340, and expandable suture capturecomponent 3308 of suturing device 3320. First or outer layer 4803A ofexpandable suture capture component 4808 is coupled to a distal end 4811of transmission shaft 4870. Inner shaft 4840 extends throughtransmission shaft 4870 and second or inner layer 4803B of expandablesuture capture component 4808 is coupled to a distal end 4845 of innershaft 4840. Each layer 4803A, 4803B is formed from a self-expandingmaterial, and each layer may be spot welded, laser welded or securedusing a bonding sleeve or adhesive to transmission shaft 4870 and innershaft 4840 as would be apparent to one skilled in the relevant art.

Transmission shaft 4870 and inner shaft 4840 are independently orseparately controlled at a proximal end of the suturing device (notshown) and, as such, expansion or deployment of outer and inner layers4803A, 4803B of expandable suture capture component 4808 areindependently or separately controlled by operation of its respectiveshaft, i.e., operation of transmission shaft 4870 controls expansion ordeployment of outer layer 4803A coupled thereto and operation of innershaft 4840 controls expansion or deployment of inner layer 4803B coupledthereto. Independent control of each layer may allow a user to bettersecure the suture ends within expandable suture capture component 4808.For example, after a suture is positioned through both layers ofexpandable suture capture component 4808, a user may selectivelycontract inner layer 4803B in order to bend the suture ends with respectto outer layer 4803A, thereby improving retention of the suture endwithin expandable suture capture component 4808. The deployedconfiguration of dual layer expandable suture capture component 4808 isexemplary and other deployed configurations may be utilized. Forexample, FIG. 48A illustrates a dual layer expandable suture capturecomponent 4808A having an open-ended disc-shaped deployed or expandedconfiguration and FIG. 48B illustrates a dual layer expandable suturecapture component 4808B having an open-ended cone-shaped deployed orexpanded configuration.

While various embodiments according to the present invention have beendescribed above, it should be understood that they have been presentedby way of illustration and example only, and not limitation. It will beapparent to persons skilled in the relevant art that various changes inform and detail can be made therein without departing from the spiritand scope of the invention. Thus, the breadth and scope of the presentinvention should not be limited by any of the above-described exemplaryembodiments, but should be defined only in accordance with the appendedclaims and their equivalents. It will also be understood that eachfeature of each embodiment discussed herein, and of each reference citedherein, can be used in combination with the features of any otherembodiment. All patents and publications discussed herein areincorporated by reference herein in their entirety.

What is claimed is:
 1. A suturing device, comprising: a handle; anelongated body coupled to a distal end of the handle; a shaft slidinglydisposed within the handle and the elongated body, wherein an expandablesuture capture component is mounted on a distal portion of the shaft,the expandable suture capture component being operable to alternatebetween a deployed configuration in which the expandable suture capturecomponent radially expands and extends away from the elongated body anda compressed configuration in which the expandable suture capturecomponent is disposed within the elongated body, at least one pair ofneedles moveable to a deployed position in which the at least one pairof needles distally extend from the distal end of the elongated body andinto the expandable suture capture component with the expandable suturecapture component in its deployed configuration and a retracted positionin which the at least one pair of needles is disposed within theelongated body, each needle including a distal end configured topenetrate through a vessel wall.
 2. The suturing device of claim 1,wherein the expandable suture capture component includes a mesh tubularstructure.
 3. The suturing device of claim 1, wherein the expandablesuture capture component includes a plurality of looped segments.
 4. Thesuturing device of claim 1, wherein the looped segments are formed froma self-expanding material.
 5. The suturing device of claim 1, whereinthe deployed configuration of the expandable suture capture component isdisc-shaped.
 6. The suturing device of claim 1, wherein the deployedconfiguration of the expandable suture capture component is cone-shaped.7. The suturing device of claim 1, wherein the expandable suture capturecomponent has two mesh layers.
 8. The suturing device of claim 1,further comprising: a suture slidingly disposed through a lumen of eachneedle, a first end of each suture being disposed within its respectiveneedle when the needle is in its deployed position, wherein each sutureis moveable relative to its respective needle to a deployed position inwhich the first end of the suture extends distally from the distal endof its respective needle.
 9. The suturing device of claim 8, whereineach suture remains in its deployed position when its respective needleis moved to its retracted position.
 10. The suturing device of claim 1,wherein the elongated body comprises: an outer shaft, wherein the outershaft defines a central lumen there through and at least two grooves forslidingly receiving the pair of needles there through; a distal guidingcomponent coupled to a distal end of the outer shaft, wherein the distalguiding component includes a central lumen there through mating with thecentral lumen of the outer shaft and at least two lumens mating with theat least two grooves of the outer shaft for guiding the pair of needlesbetween the retracted position and the deployed position.
 11. A suturingdevice for positioning a suture in situ, comprising: a handle having afirst actuation mechanism and a second actuation mechanism, wherein thesecond actuation mechanism includes a suture holder and a needle holderdisposed within the handle; an elongated body coupled to a distal end ofthe handle; a shaft slidingly disposed within the handle and theelongated body, the shaft being moveable via the first actuationmechanism, wherein an expandable suture capture component is mounted ona distal portion of the shaft and the expandable suture capturecomponent is moveable between a deployed configuration in which theexpandable suture capture component radially expands and extends awayfrom the elongated body and a compressed configuration in which theexpandable suture capture component is disposed within the elongatedbody, a pair of needles extending through the handle and through theelongated body, each needle including a distal end configured topenetrate through a vessel wall, wherein the pair of needles is coupledto the needle holder and wherein the second actuation mechanism movesthe pair of needles to a deployed position in which the pair of needlesdistally extend away from the distal end of the elongated body and intothe expandable suture capture component with the expandable suturecapture component in its deployed configuration and a retracted positionin which the pair of needles is disposed within the elongated body; anda pair of sutures slidingly disposed through the pair of needles,wherein the sutures are coupled to the suture holder when the needlesare in their deployed position and are disengaged from the suture holderwhen the needles are in their retracted position and wherein the secondactuation mechanism moves the pair of sutures relative to the pair ofneedles from a loaded position in which each first end of each suture isdisposed within its respective needle to a deployed position in whicheach first end of each suture extends distally beyond the distal end ofits respective needle.
 12. The suturing device of claim 11, wherein theexpandable suture capture component includes a mesh tubular structure.13. The suturing device of claim 11, wherein the expandable suturecapture component includes a plurality of looped segments.
 14. Thesuturing device of claim 11, wherein the deployed configuration of theexpandable suture capture component is disc-shaped.
 15. The suturingdevice of claim 11, wherein the deployed configuration of the expandablesuture capture component is cone-shaped.
 16. The suturing device ofclaim 11, wherein the expandable suture capture component has two meshlayers.
 17. A method of positioning a suture at an arteriotomy of avessel wall of a vessel, wherein the method includes the steps of:positioning a distal end of a suturing device through the arteriotomy,wherein the suturing device includes a handle, an elongated body,coupled to a distal end of the handle, and a shaft slidingly disposedwithin the handle and the elongated body, wherein an expandable suturecapture component is mounted on a distal portion of the shaft and is ina compressed configuration in which the expandable suture capturecomponent is disposed within the elongated body; expanding theexpandable suture capture component to a deployed configuration in whichthe expandable suture capture component radially expands and extendsaway from the elongated body, wherein the expanded expandable suturecapture component is positioned within the vessel; and distallyextending at least one pair of needles of the suturing device from aloaded position in which the at least one pair of needles is disposedwithin the elongated body to a deployed position in which the at leastone pair of needles distally extend from a distal end of the elongatedbody and penetrate through the vessel wall and through the expandedexpandable suture capture component, wherein a suture is slidinglydisposed through the lumen of each needle and each suture isconcurrently carried with its respective needle during the step ofdistally extending the at least one pair of needles to the deployedposition.
 18. The method of claim 17, further comprising the steps of:distally advancing the sutures relative to their respective needles froma loaded position in which a first end of each suture is disposed withinits respective needle to a deployed position in which the first end ofeach suture extends distally away from the distal end of its respectiveneedle; retracting the at least one pair of needles to a retractedposition in which the at least one pair of needles is disposed withinthe elongated body, wherein the sutures remain in their deployedpositions within an interior volume of the expandable suture capturecomponent during the step of retracting the at least one pair ofneedles; and collapsing the expandable suture capture component to thecompressed configuration, thereby pulling the first ends of the suturesinto the elongated body of the suturing device.
 19. The method of claim17, wherein the step of expanding the expandable suture capturecomponent includes distally advancing the shaft to expose the expandablesuture capture component.
 20. The method of claim 19, wherein theexpandable suture capture component is formed from a self-expandingmaterial.